Image capture and processing device for a print on demand digital camera system

ABSTRACT

An image capture and processing device includes an image sensor integrated circuit. A plurality of analogue-to-digital converters (ADC&#39;s) are connected to the image sensor integrated circuit to convert analogue signals generated by the image sensor integrated circuit into digital signals. Image processing circuitry is connected to the ADC&#39;s to carry out image processing operations on the digital signals. A print head interface is connected to the image processing circuitry to receive data from the image processing circuitry and to format that data correctly for a printhead.

CROSS REFERENCES TO RELATED APPLICATIONS

The present application is a Continuation of U.S. application Ser. No. 09/112,774, filed on Jul. 10, 1998, now abandoned.

FIELD OF THE INVENTION

The present invention relates substantially to the concept of a disposable camera having instant printing capabilities and in particular, discloses an image capture and processing device for a digital camera system.

BACKGROUND OF THE INVENTION

Recently, the concept of a “single use” disposable camera has become an increasingly popular consumer item. Disposable camera systems presently on the market normally include an internal film roll and a simplified gearing mechanism for traversing the film roll across an imaging system including a shutter and lensing system. The user, after utilising a single film roll returns the camera system to a film development centre for processing. The film roll is taken out of the camera system and processed and the prints returned to the user. The camera system is then able to be re-manufactured through the insertion of a new film roll into the camera system, the replacement of any worn or wearable parts and the re-packaging of the camera system in accordance with requirements. In this way, the concept of a single use “disposable” camera is provided to the consumer.

Recently, a camera system has been proposed by the present applicant which provides for a handheld camera device having an internal print head, image sensor and processing means such that images sense by the image sensing means, are processed by the processing means and adapted to be instantly printed out by the printing means on demand. The proposed camera system further discloses a system of internal “print rolls” carrying print media such as film on to which images are to be printed in addition to ink to supplying the printing means for the printing process. The print roll is further disclosed to be detachable and replaceable within the camera system.

Unfortunately, such a system is likely to only be constructed at a substantial cost and it would be desirable to provide for a more inexpensive form of instant camera system which maintains a substantial number of the quality aspects of the aforementioned arrangement.

It would be further advantageous to provide for the effective interconnection of the sub components of a camera system.

SUMMARY OF THE INVENTION

In accordance with a first aspect of the invention, there is provided an image capture and processing device which comprises

-   -   an image sensor integrated circuit;     -   a plurality of analogue-to-digital converters (ADC's) that are         connected to the image sensor integrated circuit to convert         analogue signals generated by the image sensor integrated         circuit into digital signals;     -   image processing circuitry that is connected to the ADC's to         carry out image processing operations on the digital signals and     -   a print head interface that is connected to the image processing         circuitry to receive data from the image processing circuitry         and to format that data correctly for a printhead.

A memory device may be interposed between the image sensor integrated circuit and the image processing circuitry to store data relating to an image sensed by the image sensor integrated circuit.

The image sensor integrated circuit may define a CMOS active pixel sensor array. The image sensor integrated circuit may incorporate a plurality of analog signal processors that are configured to carry out enhancement processes on analog signals generated by the active pixel sensor array.

The image processing circuitry may include color interpolation circuitry to interpolate pixel data.

The image processing circuitry may include convolver circuitry that is configured to apply a convolution process to the image data.

The print head interface may be configured to format the data correctly for a pagewidth printhead.

The device may be a single integrated circuit.

The invention extends to a camera system that includes an image capture and processing device as described above.

In accordance with a second aspect of the present invention, there is provided in a camera system comprising: an image sensor device for sensing an image; a processing means for processing the sensed image; a print media supply means for the supply of print media to a print head; a print head for printing the sensed image on the print media stored internally to the camera system; a portable power supply interconnected to the print head, the sensor and the processing means; and a guillotine mechanism located between the print media supply means and the print head and adapted to cut the print media into sheets of a predetermined size.

Further, preferably, the guillotine mechanism is detachable from the camera system. The guillotine mechanism can be attached to the print media supply means and is detachable from the camera system with the print media supply means. The guillotine mechanism can be mounted on a platen unit below the print head.

BRIEF DESCRIPTION OF THE DRAWINGS

Notwithstanding any other forms which may fall within the scope of the present invention, preferred forms of the invention will now be described, by way of example only, with reference to the accompanying drawings in which:

FIG. 1 illustrates a front perspective view of the assembled camera of the preferred embodiment;

FIG. 2 illustrates a rear perspective view, partly exploded, of the preferred embodiment;

FIG. 3 is a perspective view of the chassis of the preferred embodiment;

FIG. 4 is a perspective view of the chassis illustrating mounting of electric motors;

FIG. 5 is an exploded perspective of the ink supply mechanism of the preferred embodiment;

FIG. 6 is rear perspective of the assembled form of the ink supply mechanism of the preferred embodiment;

FIG. 7 is a front perspective view of the assembled form of the ink supply mechanism of the preferred embodiment;

FIG. 8 is an exploded perspective view of the platen unit of the preferred embodiment;

FIG. 9 is a perspective view of the assembled form of the platen unit;

FIG. 10 is also a perspective view of the assembled form of the platen unit;

FIG. 11 is an exploded perspective view of the printhead recapping mechanism of the preferred embodiment;

FIG. 12 is a close up exploded perspective of the recapping mechanism of the preferred embodiment;

FIG. 13 is an exploded perspective of the ink supply cartridge of the preferred embodiment;

FIG. 14 is a close up perspective, view partly in section, of the internal portions of the ink supply cartridge in an assembled form;

FIG. 15 is a schematic block diagram of one form of integrated circuit layer of the image capture and processing integrated circuit of the preferred embodiment;

FIG. 16 is an exploded view perspective illustrating the assembly process of the preferred embodiment;

FIG. 17 illustrates a front exploded perspective view of the assembly process of the preferred embodiment;

FIG. 18 illustrates a perspective view of the assembly process of the preferred embodiment;

FIG. 19 illustrates a perspective view of the assembly process of the preferred embodiment;

FIG. 20 is a perspective view illustrating the insertion of the platen unit in the preferred embodiment;

FIG. 21 illustrates the interconnection of the electrical components of the preferred embodiment;

FIG. 22 illustrates the process of assembling the preferred embodiment; and

FIG. 23 is a perspective view further illustrating the assembly process of the preferred embodiment.

DESCRIPTION OF PREFERRED AND OTHER EMBODIMENTS

Turning initially simultaneously to FIG. 1 and FIG. 2 there are illustrated perspective views of an assembled camera constructed in accordance with the preferred embodiment with FIG. 1 showing a front perspective view and FIG. 2 showing a rear perspective view. The camera 1 includes a paper or plastic film jacket 2 which can include simplified instructions 3 for the operation of the camera system 1. The camera system 1 includes a first “take” button 4 which is depressed to capture an image. The captured image is output via output slot 6. A further copy of the image can be obtained through depressing a second “printer copy” button 7 whilst an LED light 5 is illuminated. The camera system also provides the usual view finder 8 in addition to a CCD image capture/lensing system 9.

The camera system 1 provides for a standard number of output prints after which the camera system 1 ceases to function. A prints left indicator slot 10 is provided to indicate the number of remaining prints. A refund scheme at the point of purchase is assumed to be operational for the return of used camera systems for recycling.

Turning now to FIG. 3, the assembly of the camera system is based around an internal chassis 12 which can be a plastic injection molded part. A pair of paper pinch rollers 28, 29 utilized for decurling are snap fitted into corresponding frame holes eg. 26, 27.

As shown in FIG. 4, the chassis 12 includes a series of mutually opposed prongs eg. 13, 14 into which is snapped fitted a series of electric motors 16, 17. The electric motors 16, 17 can be entirely standard with the motor 16 being of a stepper motor type. The motor 16, 17 include cogs 19, 20 for driving a series of gear wheels. A first set of gear wheels is provided for controlling a paper cutter mechanism and a second set is provided for controlling print roll movement.

Turning next to FIGS. 5 to 7, there is illustrated an ink supply mechanism 40 utilized in the camera system. FIG. 5 illustrates a back exploded perspective view, FIG. 6 illustrates a back assembled view and FIG. 7 illustrates a front assembled view. The ink supply mechanism 40 is based around an ink supply cartridge 42 which contains printer ink and a print head mechanism for printing out pictures on demand. The ink supply cartridge 42 includes a side aluminium strip 43 which is provided as a shear strip to assist in cutting images from a paper roll.

A dial mechanism 44 is provided for indicating the number of “prints left”. The dial mechanism 44 is snap fitted through a corresponding mating portion 46 so as to be freely rotatable.

As shown in FIG. 6, the mechanism 40 includes a flexible PCB strip 47 which interconnects with the print head and provides for control of the print head. The interconnection between the Flex PCB strip and an image sensor and print head integrated circuit can be via Tape Automated Bonding (TAB) Strips 51, 58. A moulded aspherical lens and aperture shim 50 (FIG. 5) is also provided for imaging an image onto the surface of the image sensor integrated circuit normally located within cavity 53 and a light box module or hood 52 is provided for snap fitting over the cavity 53 so as to provide for proper light control. A series of decoupling capacitors eg. 34 can also be provided. Further a plug 45 (FIG. 7) is provided for re-plugging ink holes after refilling. A series of guide prongs eg. 55-57 are further provided for guiding the flexible PCB strip 47.

The ink supply mechanism 40 interacts with a platen unit 60 which guides print media under a printhead located in the ink supply mechanism. FIG. 8 shows an exploded view of the platen unit 60, while FIGS. 9 and 10 show assembled views of the platen unit. The platen unit 60 includes a first pinch roller 61 which is snap fitted to one side of a platen base 62. Attached to a second side of the platen base 62 is a cutting mechanism 63 which traverses the platen unit 60 by means of a rod 64 having a screw thread which is rotated by means of cogged wheel 65 which is also fitted to the platen base 62. The screw threaded rod 64 mounts a block 67 which includes a cutting wheel 68 fastened via a fastener 69. Also mounted to the block 67 is a counter actuator which includes a pawl 71. The pawl 71 acts to rotate the dial mechanism 44 of FIG. 6 upon the return traversal of the cutting wheel. As shown previously in FIG. 6, the dial mechanism 44 includes a cogged surface which interacts with pawl 71, thereby maintaining a count of the number of photographs by means of numbers embossed on the surface of dial mechanism 44. The cutting mechanism 63 is inserted into the platen base 62 by means of a snap fit via clips 74.

The platen unit 60 includes an internal recapping mechanism 80 for recapping the print head when not in use. The recapping mechanism 80 includes a sponge portion 81 and is operated via a solenoid coil so as to provide for recapping of the print head. In the preferred embodiment, there is provided an inexpensive form of printhead re-capping mechanism provided for incorporation into a handheld camera system so as to provide for printhead re-capping of an inkjet printhead.

FIG. 11 illustrates an exploded view of the recapping mechanism whilst FIG. 12 illustrates a close up of the end portion thereof. The re-capping mechanism 80 is structured around a solenoid including a 16 turn coil 75 which can comprise insulated wire. The coil 75 is turned around a first stationery solenoid arm 76 which is mounted on a bottom surface of the platen base 62 (FIG. 8) and includes a post portion 77 to magnify effectiveness of operation. The arm 76 can comprise a ferrous material.

A second moveable arm 78 of the solenoid actuator is also provided. The arm 78 is moveable and is also made of ferrous material. Mounted on the arm is a sponge portion surrounded by an elastomer strip 79. The elastomer strip 79 is of a generally arcuate cross-section and act as a leaf spring against the surface of the printhead ink supply cartridge 42 (FIG. 5) so as to provide for a seal against the surface of the printhead ink supply cartridge 42. In the quiescent position an elastomer spring unit 87, 88 acts to resiliently deform the elastomer seal 79 against the surface of the ink supply unit 42.

When it is desired to operate the printhead unit, upon the insertion of paper, the solenoid coil 75 is activated so as to cause the arm 78 to move down to be adjacent to the end plate 76. The arm 78 is held against end plate 76 while the printhead is printing by means of a small “keeper current” in coil 75. Simulation results indicate that the keeper current can be significantly less than the actuation current. Subsequently, after photo printing, the paper is guillotined by the cutting mechanism 63 of FIG. 8 acting against Aluminium Strip 43, and rewound so as to clear the area of the re-capping mechanism 80. Subsequently, the current is turned off and springs 87, 88 return the arm 78 so that the elastomer seal is again resting against the printhead ink supply cartridge.

It can be seen that the preferred embodiment provides for a simple and inexpensive means of re-capping a printhead through the utilisation of a solenoid type device having a long rectangular form. Further, the preferred embodiment utilises minimal power in that currents are only required whilst the device is operational and additionally, only a low keeper current is required whilst the printhead is printing.

Turning next to FIGS. 13 and 14, FIG. 13 illustrates an exploded perspective of the ink supply cartridge 42 whilst FIG. 14 illustrates a close up sectional view of a bottom of the ink supply cartridge with the printhead unit in place. The ink supply cartridge 42 is based around a pagewidth printhead 102 which comprises a long slither of silicon having a series of holes etched on the back surface for the supply of ink to a front surface of the silicon wafer for subsequent ejection via a micro electro mechanical system. The form of ejection can be many different forms such as those set out in the tables below.

Of course, many other inkjet technologies, as referred to the attached tables below, can also be utilised when constructing a printhead unit 102. The fundamental requirement of the ink supply cartridge 42 is the supply of ink to a series of colour channels etched through the back surface of the printhead 102. In the description of the preferred embodiment, it is assumed that a three colour printing process is to be utilised so as to provide full colour picture output. Hence, the print supply unit includes three ink supply reservoirs being a cyan reservoir 104, a magenta reservoir 105 and a yellow reservoir 106. Each of these reservoirs is required to store ink and includes a corresponding sponge type material 107-109 which assists in stabilising ink within the corresponding ink channel and inhibiting the ink from sloshing back and forth when the printhead is utilised in a handheld camera system. The reservoirs 104, 105, 106 are formed through the mating of first exterior plastic piece 110 and a second base piece 111.

At a first end 118 of the base piece 111 a series of air inlet 113-115 are provided. Each air inlet leads to a corresponding winding channel which is hydrophobically treated so as to act as an ink repellent and therefore repel any ink that may flow along the air inlet channel. The air inlet channel further takes a convoluted path assisting in resisting any ink flow out of the chambers 104-106. An adhesive tape portion 117 is provided for sealing the channels within end portion 118.

At the top end, there is included a series of refill holes (not shown) for refilling corresponding ink supply chambers 104, 105, 106. A plug 121 is provided for sealing the refill holes.

Turning now to FIG. 14, there is illustrated a close up perspective view, partly in section through the ink supply cartridge 42 of FIG. 13 when formed as a unit. The ink supply cartridge includes the three colour ink reservoirs 104, 105, 106 which supply ink to different portions of the back surface of printhead 102 which includes a series of apertures 128 defined therein for carriage of the ink to the front surface.

The ink supply cartridge 42 includes two guide walls 124, 125 which separate the various ink chambers and are tapered into an end portion abutting the surface of the printhead 102. The guide walls 124, 125 are further mechanically supported by block portions eg. 126 which are placed at regular intervals along the length of the ink supply unit. The block portions 126 leave space at portions close to the back of printhead 102 for the flow of ink around the back surface thereof.

The ink supply unit is preferably formed from a multi-part plastic injection mould and the mould pieces eg. 110, 111 (FIG. 13) snap together around the sponge pieces 107, 109. Subsequently, a syringe type device can be inserted in the ink refill holes and the ink reservoirs filled with ink with the air flowing out of the air outlets 113-115. Subsequently, the adhesive tape portion 117 and plug 121 are attached and the printhead tested for operation capabilities. Subsequently, the ink supply cartridge 42 can be readily removed for refilling by means of removing the ink supply cartridge, performing a washing cycle, and then utilising the holes for the insertion of a refill syringe filled with ink for refilling the ink chamber before returning the ink supply cartridge 42 to a camera.

Turning now to FIG. 15, there is shown an example layout of the Image Capture and Processing integrated circuit (ICP) 48.

The Image Capture and Processing integrated circuit 48 provides most of the electronic functionality of the camera with the exception of the print head integrated circuit. The integrated circuit 48 is a highly integrated system. It combines CMOS image sensing, analog to digital conversion, digital image processing, DRAM storage, ROM, and miscellaneous control functions in a single integrated circuit.

The integrated circuit is estimated to be around 32 mm² using a leading edge 0.18 micron CMOS/DRAM/APS process. The integrated circuit size and cost can scale somewhat with Moore's law, but is dominated by a CMOS active pixel sensor array 201, so scaling is limited as the sensor pixels approach the diffraction limit.

The ICP 48 includes CMOS logic, a CMOS image sensor, DRAM, and analog circuitry. A very small amount of flash memory or other non-volatile memory is also preferably included for protection against reverse engineering.

Alternatively, the ICP can readily be divided into two integrated circuits: one for the CMOS imaging array, and the other for the remaining circuitry. The cost of this two integrated circuit solution should not be significantly different than the single integrated circuit ICP, as the extra cost of packaging and bond-pad area is somewhat cancelled by the reduced total wafer area requiring the color filter fabrication steps.

The ICP preferably contains the following functions:

Function 1.5 megapixel image sensor Analog Signal Processors Image sensor column decoders Image sensor row decoders Analogue to Digital Conversion (ADC) Column ADC's Auto exposure 12 Mbits of DRAM DRAM Address Generator Color interpolator Convolver Color ALU Halftone matrix ROM Digital halftoning Print head interface 8 bit CPU core Program ROM Flash memory Scratchpad SRAM Parallel interface (8 bit) Motor drive transistors (5) Clock PLL JTAG test interface Test circuits Busses Bond pads

The CPU, DRAM, Image sensor, ROM, Flash memory, Parallel interface, JTAG interface and ADC can be vendor supplied cores. The ICP is intended to run on 1.5V to minimize power consumption and allow convenient operation from two AA type battery cells.

FIG. 15 illustrates a layout of the ICP 48. The ICP 48 is dominated by the imaging array 201, which consumes around 80% of the integrated circuit area. The imaging array is a CMOS 4 transistor active pixel design with a resolution of 1,500×1,000. The array can be divided into the conventional configuration, with two green pixels, one red pixel, and one blue pixel in each pixel group. There are 750×500 pixel groups in the imaging array.

The latest advances in the field of image sensing and CMOS image sensing in particular can be found in the October, 1997 issue of IEEE Transactions on Electron Devices and, in particular, pages 1689 to 1968. Further, a specific implementation similar to that disclosed in the present application is disclosed in Wong et. al, “CMOS Active Pixel Image Sensors Fabricated Using a 1.8V, 0.25 μm CMOS Technology”, IEDM 1996, page 915

The imaging array uses a 4 transistor active pixel design of a standard configuration. To minimize integrated circuit area and therefore cost, the image sensor pixels should be as small as feasible with the technology available. With a four transistor cell, the typical pixel size scales as 20 times the lithographic feature size. This allows a minimum pixel area of around 3.6 μm×3.6 μm. However, the photosite must be substantially above the diffraction limit of the lens. It is also advantageous to have a square photosite, to maximize the margin over the diffraction limit in both horizontal and vertical directions. In this case, the photosite can be specified as 2.5 μm×2.5 μm. The photosite can be a photogate, pinned photodiode, charge modulation device, or other sensor.

The four transistors are packed as an ‘L’ shape, rather than a rectangular region, to allow both the pixel and the photosite to be square. This reduces the transistor packing density slightly, increasing pixel size. However, the advantage in avoiding the diffraction limit is greater than the small decrease in packing density.

The transistors also have a gate length which is longer than the minimum for the process technology. These have been increased from a drawn length of 0.18 micron to a drawn length of 0.36 micron. This is to improve the transistor matching by making the variations in gate length represent a smaller proportion of the total gate length.

The extra gate length, and the ‘L’ shaped packing, mean that the transistors use more area than the minimum for the technology. Normally, around 8 μm² would be required for rectangular packing. Preferably, 9.75 μm² has been allowed for the transistors.

The total area for each pixel is 16 μm², resulting from a pixel size of 4 μm×4 μm. With a resolution of 1,500×1,000, the area of the imaging array 101 is 6,000 μm×4,000 μm, or 24 mm².

The presence of a color image sensor on the integrated circuit affects the process required in two major ways:

-   -   The CMOS fabrication process should be optimized to minimize         dark current

Color filters are required. These can be fabricated using dyed photosensitive polyimides, resulting in an added process complexity of three spin coatings, three photolithographic steps, three development steps, and three hardbakes.

There are 15,000 analog signal processors (ASPs) 205, one for each of the columns of the sensor. The ASPs amplify the signal, provide a dark current reference, sample and hold the signal, and suppress the fixed pattern noise (FPN).

There are 375 analog to digital converters 206, one for each four columns of the sensor array. These may be delta-sigma or successive approximation type ADC's. A row of low column ADC's are used to reduce the conversion speed required, and the amount of analog signal degradation incurred before the signal is converted to digital. This also eliminates the hot spot (affecting local dark current) and the substrate coupled noise that would occur if a single high speed ADC was used. Each ADC also has two four bit DAC's which trim the offset and scale of the ADC to further reduce FPN variations between columns. These DAC's are controlled by data stored in flash memory during integrated circuit testing.

The column select logic 204 is a 1:1500 decoder which enables the appropriate digital output of the ADCs onto the output bus. As each ADC is shared by four columns, the least significant two bits of the row select control 4 input analog multiplexors.

A row decoder 207 is a 1:1000 decoder which enables the appropriate row of the active pixel sensor array. This selects which of the 1000 rows of the imaging array is connected to analog signal processors. As the rows are always accessed in sequence, the row select logic can be implemented as a shift register.

An auto exposure system 208 adjusts the reference voltage of the ADC 205 in response to the maximum intensity sensed during the previous frame period. Data from the green pixels is passed through a digital peak detector. The peak value of the image frame period before capture (the reference frame) is provided to a digital to analogue converter(DAC), which generates the global reference voltage for the column ADCs. The peak detector is reset at the beginning of the reference frame. The minimum and maximum values of the three RGB color components are also collected for color correction.

The second largest section of the integrated circuit is consumed by a DRAM 210 used to hold the image. To store the 1,500×1,000 image from the sensor without compression, 1.5 Mbytes of DRAM 210 are required. This equals 12 Mbits, or slightly less than 5% of a 256 Mbit DRAM. The DRAM technology assumed is of the 256 Mbit generation implemented using 0.18 μm CMOS.

Using a standard 8F cell, the area taken by the memory array is 3.11 mm². When row decoders, column sensors, redundancy, and other factors are taken into account, the DRAM requires around 4 mm².

This DRAM 210 can be mostly eliminated if analog storage of the image signal can be accurately maintained in the CMOS imaging array for the two seconds required to print the photo. However, digital storage of the image is preferable as it is maintained without degradation, is insensitive to noise, and allows copies of the photo to be printed considerably later.

A DRAM address generator 211 provides the write and read addresses to the DRAM 210. Under normal operation, the write address is determined by the order of the data read from the CMOS image sensor 201. This will typically be a simple raster format. However, the data can be read from the sensor 201 in any order, if matching write addresses to the DRAM are generated. The read order from the DRAM 210 will normally simply match the requirements of a color interpolator and the print head. As the cyan, magenta, and yellow rows of the print head are necessarily offset by a few pixels to allow space for nozzle actuators, the colors are not read from the DRAM simultaneously. However, there is plenty of time to read all of the data from the DRAM many times during the printing process. This capability is used to eliminate the need for FIFOs in the print head interface, thereby saving integrated circuit area. All three RGB image components can be read from the DRAM each time color data is required. This allows a color space converter to provide a more sophisticated conversion than a simple linear RGB to CMY conversion.

Also, to allow two dimensional filtering of the image data without requiring line buffers, data is re-read from the DRAM array.

The address generator may also implement image effects in certain models of camera. For example, passport photos are generated by a manipulation of the read addresses to the DRAM. Also, image framing effects (where the central image is reduced), image warps, and kaleidoscopic effects can all be generated by manipulating the read addresses of the DRAM.

While the address generator 211 may be implemented with substantial complexity if effects are built into the standard integrated circuit, the integrated circuit area required for the address generator is small, as it consists only of address counters and a moderate amount of random logic.

A color interpolator 214 converts the interleaved pattern of red, 2×green, and blue pixels into RGB pixels. It consists of three 8 bit adders and associated registers. The divisions are by either 2 (for green) or 4 (for red and blue) so they can be implemented as fixed shifts in the output connections of the adders.

A convolver 215 is provided as a sharpening filter which applies a small convolution kernel (5×5) to the red, green, and blue planes of the image. The convolution kernel for the green plane is different from that of the red and blue planes, as green has twice as many samples. The sharpening filter has five functions:

-   -   To improve the color interpolation from the linear interpolation         provided by the color interpolator, to a close approximation of         a sinc interpolation.     -   To compensate for the image ‘softening’ which occurs during         digitization.     -   To adjust the image sharpness to match average consumer         preferences, which are typically for the image to be slightly         sharper than reality. As the single use camera is intended as a         consumer product, and not a professional photographic products,         the processing can match the most popular settings, rather than         the most accurate.     -   To suppress the sharpening of high frequency (individual pixel)         noise. The function is similar to the ‘unsharp mask’ process.     -   To antialias Image Warping.

These functions are all combined into a single convolution matrix. As the pixel rate is low (less than 1 Mpixel per second) the total number of multiplies required for the three color channels is 56 million multiplies per second. This can be provided by a single multiplier. Fifty bytes of coefficient ROM are also required.

A color ALU 113 combines the functions of color compensation and color space conversion into the one matrix multiplication, which is applied to every pixel of the frame. As with sharpening, the color correction should match the most popular settings, rather than the most accurate.

A color compensation circuit of the color ALU provides compensation for the lighting of the photo. The vast majority of photographs are substantially improved by a simple color compensation, which independently normalizes the contrast and brightness of the three color components.

A color look-up table (CLUT) 212 is provided for each color component. These are three separate 256×8 SRAMs, requiring a total of 6,144 bits. The CLUTs are used as part of the color correction process. They are also used for color special effects, such as stochastically selected “wild color” effects.

A color space conversion system of the color ALU converts from the RGB color space of the image sensor to the CMY color space of the printer. The simplest conversion is a 1's complement of the RGB data. However, this simple conversion assumes perfect linearity of both color spaces, and perfect dye spectra for both the color filters of the image sensor, and the ink dyes. At the other extreme is a tri-linear interpolation of a sampled three dimensional arbitrary transform table. This can effectively match any non-linearity or differences in either color space. Such a system is usually necessary to obtain good color space conversion when the print engine is a color electrophotographic

However, since the non-linearity of a halftoned ink jet output is very small, a simpler system can be used. A simple matrix multiply can provide excellent results. This requires nine multiplies and six additions per contone pixel. However, since the contone pixel rate is low (less than 1 Mpixel/sec) these operations can share a single multiplier and adder. The multiplier and adder are used in a color ALU which is shared with the color compensation function.

Digital halftoning can be performed as a dispersed dot ordered dither using a stochastic optimized dither cell. A halftone matrix ROM 216 is provided for storing dither cell coefficients. A dither cell size of 32×32 is adequate to ensure that the cell repeat cycle is not visible. The three colors—cyan, magenta, and yellow—are all dithered using the same cell, to ensure maximum co-positioning of the ink dots. This minimizes ‘muddying’ of the mid-tones which results from bleed of dyes from one dot to adjacent dots while still wet. The total ROM size required is 1 KByte, as the one ROM is shared by the halftoning units for each of the three colors.

The digital halftoning used is dispersed dot ordered dither with stochastic optimized dither matrix. While dithering does not produce an image quite as ‘sharp’ as error diffusion, it does produce a more accurate image with fewer artifacts. The image sharpening produced by error diffusion is artificial, and less controllable and accurate than ‘unsharp mask’ filtering performed in the contone domain. The high print resolution (1,600 dpi×1,600 dpi) results in excellent quality when using a well formed stochastic dither matrix.

Digital halftoning is performed by a digital halftoning unit 217 using a simple comparison between the contone information from the DRAM 210 and the contents of the dither matrix 216. During the halftone process, the resolution of the image is changed from the 250 dpi of the captured contone image to the 1,600 dpi of the printed image. Each contone pixel is converted to an average of 40.96 halftone dots.

The ICP incorporates a 16 bit microcontroller CPU core 219 to run the miscellaneous camera functions, such as reading the buttons, controlling the motor and solenoids, setting up the hardware, and authenticating the refill station. The processing power required by the CPU is very modest, and a wide variety of processor cores can be used. As the entire CPU program is run from a small ROM 220[.], program compatibility between camera versions is not important, as no external programs are run. A 2 Mbit (256 Kbyte) program and data ROM 220 is included on integrated circuit. Most of this ROM space is allocated to data for outline graphics and fonts for specialty cameras. The program requirements are minor. The single most complex task is the encrypted authentication of the refill station. The ROM requires a single transistor per bit.

A Flash memory 221 may be used to store a 128 bit authentication code. This provides higher security than storage of the authentication code in ROM, as reverse engineering can be made essentially impossible. The Flash memory is completely covered by third level metal, making the data impossible to extract using scanning probe microscopes or electron beams. The authentication code is stored in the integrated circuit when manufactured. At least two other Flash bits are required for the authentication process: a bit which locks out reprogramming of the authentication code, and a bit which indicates that the camera has been refilled by an authenticated refill station. The flash memory can also be used to store FPN correction data for the imaging array. Additionally, a phase locked loop rescaling parameter is stored for scaling the clocking cycle to an appropriate correct time. The clock frequency does not require crystal accuracy since no date functions are provided. To eliminate the cost of a crystal, an on integrated circuit oscillator with a phase locked loop 224 is used. As the frequency of an on-integrated circuit oscillator is highly variable from integrated circuit to integrated circuit, the frequency ratio of the oscillator to the PLL is digitally trimmed during initial testing. The value is stored in Flash memory 221. This allows the clock PLL to control the ink-jet heater pulse width with sufficient accuracy.

A scratchpad SRAM is a small static RAM 222 with a 6T cell. The scratchpad provided temporary memory for the 16 bit CPU. 1024 bytes is adequate.

A print head interface 223 formats the data correctly for the print head. The print head interface also provides all of the timing signals required by the print head. These timing signals may vary depending upon temperature, the number of dots printed simultaneously, the print medium in the print roll, and the dye density of the ink in the print roll.

The following is a table of external connections to the print head interface:

Connection Function Pins DataBits[0-7] Independent serial data to the eight 8 segments of the print head BitClock Main data clock for the print head 1 ColorEnable[0-2] Independent enable signals for the CMY 3 actuators, allowing different pulse times for each color. BankEnable[0-1] Allows either simultaneous or interleaved 2 actuation of two banks of nozzles. This allows two different print speed/power consumption tradeoffs NozzleSelect[0-4] Selects one of 32 banks of nozzles for 5 simultaneous actuation ParallelXferClock Loads the parallel transfer register 1 with the data from the shift registers Total 20

The print head utilized is composed of eight identical segments, each 1.25 cm long. There is no connection between the segments on the print head integrated circuit. Any connections required are made in the external TAB bonding film, which is double sided. The division into eight identical segments is to simplify lithography using wafer steppers. The segment width of 1.25 cm fits easily into a stepper field. As the print head integrated circuit is long and narrow (10 cm×0.3 mm), the stepper field contains a single segment of 32 print head integrated circuits. The stepper field is therefore 1.25 cm×1.6 cm. An average of four complete print heads are patterned in each wafer step.

A single BitClock output line connects to all 8 segments on the print head. The 8 DataBits lines lead one to each segment, and are clocked into the 8 segments on the print head simultaneously (on a BitClock pulse). For example, dot 0 is transferred to segment₀, dot 750 is transferred to segment₁, dot 1500 to segment₂ etc simultaneously.

The ParallelXferClock is connected to each of the 8 segments on the print head, so that on a single pulse, all segments transfer their bits at the same time.

The NozzleSelect, BankEnable and ColorEnable lines are connected to each of the 8 segments, allowing the print head interface to independently control the duration of the cyan, magenta, and yellow nozzle energizing pulses. Registers in the Print Head Interface allow the accurate specification of the pulse duration between 0 and 6 ms, with a typical duration of 2 ms to 3 ms.

A parallel interface 125 connects the ICP to individual static electrical signals. The CPU is able to control each of these connections as memory mapped I/O via a low speed bus.

The following is a table of connections to the parallel interface:

Connection Direction Pins Paper transport stepper motor Output 4 Capping solenoid Output 1 Copy LED Output 1 Photo button Input 1 Copy button Input 1 Total 8

Seven high current drive transistors eg. 227 are required. Four are for the four phases of the main stepper motor, two are for the guillotine motor, and the remaining transistor is to drive the capping solenoid. These transistors are allocated 20,000 square microns (600,000 F) each. As the transistors are driving highly inductive loads, they must either be turned off slowly, or be provided with a high level of back EMF protection. If adequate back EMF protection cannot be provided using the integrated circuit process chosen, then external discrete transistors should be used. The transistors are never driven at the same time as the image sensor is used. This is to avoid voltage fluctuations and hot spots affecting the image quality. Further, the transistors are located as far away from the sensor as possible.

A standard JTAG (Joint Test Action Group) interface 228 is included in the ICP for testing purposes and for interrogation by the refill station. Due to the complexity of the integrated circuit, a variety of testing techniques are required, including BIST (Built In Self Test) and functional block isolation. An overhead of 10% in integrated circuit area is assumed for integrated circuit testing circuitry for the random logic portions. The overhead for the large arrays the image sensor and the DRAM is smaller.

The JTAG interface is also used for authentication of the refill station. This is included to ensure that the cameras are only refilled with quality paper and ink at a properly constructed refill station, thus preventing inferior quality refills from occurring. The camera must authenticate the refill station, rather than vice versa. The secure protocol is communicated to the refill station during the automated test procedure. Contact is made to four gold plated spots on the ICP/print head TAB by the refill station as the new ink is injected into the print head.

FIG. 16 illustrates a rear view of the next step in the construction process whilst FIG. 17 illustrates a front view.

Turning now to FIG. 16, the assembly of the camera system proceeds via first assembling the ink supply mechanism 40. The flex PCB is interconnected with batteries 84 only one of which is shown, which are inserted in the middle portion of a print roll 85 which is wrapped around a plastic former 86. An end cap 89 is provided at the other end of the print roll 85 so as to fasten the print roll and batteries firmly to the ink supply mechanism.

The solenoid coil is interconnected (not shown) to interconnects 97, 98 (FIG. 8) which include leaf spring ends for interconnection with electrical contacts on the Flex PCB so as to provide for electrical control of the solenoid.

Turning now to FIGS. 17-19 the next step in the construction process is the insertion of the relevant gear trains into the side of the camera chassis. FIG. 17 illustrates a front view, FIG. 18 illustrates a rear view and FIG. 19 also illustrates a rear view. The first gear train comprising gear wheels 22, 23 is utilised for driving the guillotine blade with the gear wheel 23 engaging the gear wheel 65 of FIG. 8. The second gear train comprising gear wheels 24, 25 and 26 engage one end of the print roller 61 of FIG. 8. As best indicated in FIG. 18, the gear wheels mate with corresponding pins on the surface of the chassis with the gear wheel 26 being snap fitted into corresponding mating hole 27.

Next, as illustrated in FIG. 20, the assembled platen unit 60 is then inserted between the print roll 85 and aluminium cutting blade 43.

Turning now to FIG. 21, by way of illumination, there is illustrated the electrically interactive components of the camera system. As noted previously, the components are based around a Flex PCB board and include a TAB film 58 which interconnects the printhead 102 with the image sensor and processing integrated circuit 48. Power is supplied by two AA type batteries 83, 84 and a paper drive stepper motor 16 is provided in addition to a rotary guillotine motor 17.

An optical element 31 is provided for snapping into a top portion of the chassis 12. The optical element 31 includes portions defining an optical view finder 32, 33 which are slotted into mating portions 35, 36 in view finder channel 37. Also provided in the optical element 31 is a lensing system 38 for magnification of the prints left number in addition to an optical pipe element 39 for piping light from the LED 5 for external display.

Turning next to FIG. 22, the assembled unit 90 is then inserted into a front outer case 91 which includes button 4 for activation of printouts.

Turning now to FIG. 23, next, the unit 90 is provided with a snap-on back cover 93 which includes a slot 6 and copy print button 7. A wrapper label containing instructions and advertising (not shown) is then wrapped around the outer surface of the camera system and pinch clamped to the cover by means of clamp strip 96 which can comprise a flexible plastic or rubber strip.

Subsequently, the preferred embodiment is ready for use as a one time use camera system that provides for instant output images on demand. It will be evident that the preferred embodiment further provides for a refillable camera system. A used camera can be collected and its outer plastic cases removed and recycled. A new paper roll and batteries can be added and the ink cartridge refilled. A series of automatic test routines can then be carried out to ensure that the printer is properly operational. Further, in order to ensure only authorised refills are conducted so as to enhance quality, routines in the on-integrated circuit program ROM can be executed such that the camera authenticates the refilling station using a secure protocol. Upon authentication, the camera can reset an internal paper count and an external case can be fitted on the camera system with a new outer label. Subsequent packing and shipping can then take place.

It will be further readily evident to those skilled in the art that the program ROM can be modified so as to allow for a variety of digital processing routines. In addition to the digitally enhanced photographs optimised for mainstream consumer preferences, various other models can readily be provided through mere re-programming of the program ROM. For example, a sepia classic old fashion style output can be provided through a remapping of the colour mapping function. A further alternative is to provide for black and white outputs again through a suitable colour reapplying algorithm. Minimum colour can also be provided to add a touch of colour to black and white prints to produce the effect that was traditionally used to colourize black and white photos. Further, passport photo output can be provided through suitable address remappings within the address generators. Further, edge filters can be utilised as is known in the field of image processing to produce sketched art styles. Further, classic wedding borders and designs can be placed around an output image in addition to the provision of relevant clip arts. For example, a wedding style camera might be provided. Further, a panoramic mode can be provided so as to output the well known panoramic format of images. Further, a postcard style output can be provided through the printing of postcards including postage on the back of a print roll surface. Further, cliparts can be provided for special events such as Halloween, Christmas etc. Further, kaleidoscopic effects can be provided through address remappings and wild colour effects can be provided through remapping of the colour lookup table. Many other forms of special event cameras can be provided for example, cameras dedicated to the Olympics, movie tie-ins, advertising and other special events.

The operational mode of the camera can be programmed so that upon the depressing of the take photo a first image is sampled by the sensor array to determine irrelevant parameters. Next a second image is again captured which is utilised for the output. The captured image is then manipulated in accordance with any special requirements before being initially output on the paper roll. The LED light is then activated for a predetermined time during which the DRAM is refreshed so as to retain the image. If the print copy button is depressed during this predetermined time interval, a further copy of the photo is output. After the predetermined time interval where no use of the camera has occurred, the onboard CPU shuts down all power to the camera system until such time as the take button is again activated. In this way, substantial power savings can be realized.

Ink Jet Technologies

The embodiments of the invention use an ink jet printer type device. Of course many different devices could be used. However presently popular ink jet printing technologies are unlikely to be suitable.

The most significant problem with thermal inkjet is power consumption. This is approximately 100 times that required for high speed, and stems from the energy-inefficient means of drop ejection. This involves the rapid boiling of water to produce a vapor bubble which expels the ink. Water has a very high heat capacity, and must be superheated in thermal inkjet applications. This leads to an efficiency of around 0.02%, from electricity input to drop momentum (and increased surface area) out.

The most significant problem with piezoelectric inkjet is size and cost. Piezoelectric crystals have a very small deflection at reasonable drive voltages, and therefore require a large area for each nozzle. Also, each piezoelectric actuator must be connected to its drive circuit on a separate substrate. This is not a significant problem at the current limit of around 300 nozzles per print head, but is a major impediment to the fabrication of pagewide print heads with 19,200 nozzles.

Ideally, the inkjet technologies used meet the stringent requirements of in-camera digital color printing and other high quality, high speed, low cost printing applications. To meet the requirements of digital photography, new inkjet technologies have been created. The target features include:

-   -   low power (less than 10 Watts)     -   high resolution capability (1,600 dpi or more)     -   photographic quality output     -   low manufacturing cost     -   small size (pagewidth times minimum cross section)     -   high speed (<2 seconds per page).

All of these features can be met or exceeded by the inkjet systems described below with differing levels of difficulty. 45 different inkjet technologies have been developed by the Assignee to give a wide range of choices for high volume manufacture. These technologies form part of separate applications assigned to the present Assignee as set out in the table below.

The inkjet designs shown here are suitable for a wide range of digital printing systems, from battery powered one-time use digital cameras, through to desktop and network printers, and through to commercial printing systems

For ease of manufacture using standard process equipment, the print head is designed to be a monolithic 0.5 micron CMOS integrated circuit with MEMS post processing. For color photographic applications, the print head is 100 mm long, with a width which depends upon the inkjet type. The smallest print head designed is IJ38, which is 0.35 mm wide, giving a integrated circuit area of 35 square mm. The print heads each contain 19,200 nozzles plus data and control circuitry.

Ink is supplied to the back of the print head by injection molded plastic ink channels. The molding requires 50 micron features, which can be created using a lithographically micromachined insert in a standard injection molding tool. Ink flows through holes etched through the wafer to the nozzle chambers fabricated on the front surface of the wafer. The print head is connected to the camera circuitry by tape automated bonding.

Cross-Referenced Applications

The following table is a guide to cross-referenced patent applications filed concurrently herewith and discussed hereinafter with the reference being utilized in subsequent tables when referring to a particular case:

Docket No. Reference Title IJ01US IJ01 Radiant Plunger Ink Jet Printer IJ02US IJ02 Electrostatic Ink Jet Printer IJ03US IJ03 Planar Thermoelastic Bend Actuator Ink Jet IJ04US IJ04 Stacked Electrostatic Ink Jet Printer IJ05US IJ05 Reverse Spring Lever Ink Jet Printer IJ06US IJ06 Paddle Type Ink Jet Printer IJ07US IJ07 Permanent Magnet Electromagnetic Ink Jet Printer IJ08US IJ08 Planar Swing Grill Electromagnetic Ink Jet Printer IJ09US IJ09 Pump Action Refill Ink Jet Printer IJ10US IJ10 Pulsed Magnetic Field Ink Jet Printer IJ11US IJ11 Two Plate Reverse Firing Electromagnetic Ink Jet Printer IJ12US IJ12 Linear Stepper Actuator Ink Jet Printer IJ13US IJ13 Gear Driven Shutter Ink Jet Printer IJ14US IJ14 Tapered Magnetic Pole Electromagnetic Ink Jet Printer IJ15US IJ15 Linear Spring Electromagnetic Grill Ink Jet Printer IJ16US IJ16 Lorenz Diaphragm Electromagnetic Ink Jet Printer IJ17US IJ17 PTFE Surface Shooting Shuttered Oscillating Pressure Ink Jet Printer IJ18US IJ18 Buckle Grip Oscillating Pressure Ink Jet Printer IJ19US IJ19 Shutter Based Ink Jet Printer IJ20US IJ20 Curling Calyx Thermoelastic Ink Jet Printer IJ21US IJ21 Thermal Actuated Ink Jet Printer IJ22US IJ22 Iris Motion Ink Jet Printer IJ23US IJ23 Direct Firing Thermal Bend Actuator Ink Jet Printer IJ24US IJ24 Conductive PTFE Ben Activator Vented Ink Jet Printer IJ25US IJ25 Magnetostrictive Ink Jet Printer IJ26US IJ26 Shape Memory Alloy Ink Jet Printer IJ27US IJ27 Buckle Plate Ink Jet Printer IJ28US IJ28 Thermal Elastic Rotary Impeller Ink Jet Printer IJ29US IJ29 Thermoelastic Bend Actuator Ink Jet Printer IJ30US IJ30 Thermoelastic Bend Actuator Using PTFE and Corrugated Copper Ink Jet Printer IJ31US IJ31 Bend Actuator Direct Ink Supply Ink Jet Printer IJ32US IJ32 A High Young's Modulus Thermoelastic Ink Jet Printer IJ33US IJ33 Thermally actuated slotted chamber wall ink jet printer IJ34US IJ34 Ink Jet Printer having a thermal actuator comprising an external coiled spring IJ35US IJ35 Trough Container Ink Jet Printer IJ36US IJ36 Dual Chamber Single Vertical Actuator Ink Jet IJ37US IJ37 Dual Nozzle Single Horizontal Fulcrum Actuator Ink Jet IJ38US IJ38 Dual Nozzle Single Horizontal Actuator Ink Jet IJ39US IJ39 A single bend actuator cupped paddle ink jet printing device IJ40US IJ40 A thermally actuated ink jet printer having a series of thermal actuator units IJ41US IJ41 A thermally actuated ink jet printer including a tapered heater element IJ42US IJ42 Radial Back-Curling Thermoelastic Ink Jet IJ43US IJ43 Inverted Radial Back-Curling Thermoelastic Ink Jet IJ44US IJ44 Surface bend actuator vented ink supply ink jet printer IJ45US IJ45 Coil Acutuated Magnetic Plate Ink Jet Printer Tables of Drop-on-Demand Inkjets

Eleven important characteristics of the fundamental operation of individual inkjet nozzles have been identified. These characteristics are largely orthogonal, and so can be elucidated as an eleven dimensional matrix. Most of the eleven axes of this matrix include entries developed by the present assignee.

The following tables form the axes of an eleven dimensional table of inkjet types.

-   Actuator mechanism (18 types) -   Basic operation mode (7 types) -   Auxiliary mechanism (8 types) -   Actuator amplification or modification method (17 types) -   Actuator motion (19 types) -   Nozzle refill method (4 types) -   Method of restricting back-flow through inlet (10 types) -   Nozzle clearing method (9 types) -   Nozzle plate construction (9 types) -   Drop ejection direction (5 types) -   Ink type (7 types)

The complete eleven dimensional table represented by these axes contains 36.9 billion possible configurations of inkjet nozzle. While not all of the possible combinations result in a viable inkjet technology, many million configurations are viable. It is clearly impractical to elucidate all of the possible configurations. Instead, certain inkjet types have been investigated in detail. These are designated IJ01 to IJ45 above.

Other inkjet configurations can readily be derived from these 45 examples by substituting alternative configurations along one or more of the 11 axes. Most of the IJ01 to IJ45 examples can be made into inkjet print heads with characteristics superior to any currently available inkjet technology.

Where there are prior art examples known to the inventor, one or more of these examples are listed in the examples column of the tables below. The IJ01 to IJ45 series are also listed in the examples column. In some cases, a printer may be listed more than once in a table, where it shares characteristics with more than one entry.

Suitable applications include: Home printers, Office network printers, Short run digital printers, Commercial print systems, Fabric printers, Pocket printers, Internet WWW printers, Video printers, Medical imaging, Wide format printers, Notebook PC printers, Fax machines, Industrial printing systems, Photocopiers, Photographic minilabs etc.

The information associated with the aforementioned 11 dimensional matrix are set out in the following tables.

Actuator mechanism (applied only to selected ink drops) Actuator Mechanism Description Advantages Disadvantages Examples Thermal bubble An electrothermal heater heats the Large force generated High power Canon Bubblejet 1979 ink to above boiling point, Simple construction Ink carrier limited to water Endo et al GB patent transferring significant heat to the No moving parts Low efficiency 2,007,162 aqueous ink. A bubble nucleates Fast operation High temperatures required Xerox heater-in-pit and quickly forms, expelling the Small integrated circuit area High mechanical stress 1990 Hawkins et al ink. required for actuator Unusual materials required U.S. Pat. No. The efficiency of the process is Large drive transistors 4,899,181 Hewlett- low, with typically less than Cavitation causes actuator failure Packard TIJ 1982 0.05% of the electrical energy Kogation reduces bubble formation Vaught et al U.S. Pat. being transformed into kinetic Large print heads are difficult to No. 4,490,728 energy of the drop. fabricate Piezoelectric A piezoelectric crystal such as Low power consumption Very large area required for actuator Kyser et al U.S. Pat. lead lanthanum zirconate (PZT) is Many ink types can be used Difficult to integrate with electronics No. 3,946,398 electrically activated, and either Fast operation High voltage drive transistors required Zoltan U.S. Pat. No. expands, shears, or bends to apply High efficiency Full pagewidth print heads impractical 3,683,212 1973 pressure to the ink, ejecting drops. due to actuator size Stemme U.S. Pat. No. Requires electrical poling in high field 3,747,120 Epson strengths during manufacture Stylus Tektronix IJ04 Electro-strictive An electric field is used to Low power consumption Low maximum strain (approx. 0.01%) Seiko Epson, Usui et activate electrostriction in relaxor Many ink types can be used Large area required for actuator due to all JP 253401/96 materials such as lead lanthanum Low thermal expansion low strain IJ04 zirconate titanate (PLZT) or lead Electric field strength Response speed is marginal (~10 μs) magnesium niobate (PMN). required (approx. 3.5 V/μm) High voltage drive transistors required can be generated without Full pagewidth print heads impractical difficulty due to actuator size Does not require electrical poling Ferroelectric An electric field is used to induce Low power consumption Difficult to integrate with electronics IJ04 a phase transition between the Many ink types can be used Unusual materials such as PLZSnT are antiferroelectric (AFE) and Fast operation (<1 μs) required ferroelectric (FE) phase. Relatively high longitudinal Actuators require a large area Perovskite materials such as tin strain modified lead lanthanum High efficiency zirconate titanate (PLZSnT) Electric field strength of exhibit large strains of up to 1% around 3 V/μm can be associated with the AFE to FE readily provided phase transition. Electrostatic Conductive plates are separated Low power consumption Difficult to operate electrostatic IJ02, IJ04 plates by a compressible or fluid Many ink types can be used devices in an aqueous environment dielectric (usually air). Upon Fast operation The electrostatic actuator will application of a voltage, the plates normally need to be separated from attract each other and displace the ink ink, causing drop ejection. The Very large area required to achieve conductive plates may be in a high forces comb or honeycomb structure, or High voltage drive transistors may be stacked to increase the surface required area and therefore the force. Full pagewidth print heads are not competitive due to actuator size Electrostatic A strong electric field is applied Low current consumption High voltage required 1989 Saito et al, U.S. pull on ink to the ink, whereupon electrostatic Low temperature May be damaged by sparks due to air Pat. No. 4,799,068 attraction accelerates the ink breakdown 1989 Miura et al, U.S. towards the print medium. Required field strength increases as Pat. No. 4,810,954 the drop size decreases Tone-jet High voltage drive transistors required Electrostatic field attracts dust Permanent An electromagnet directly attracts Low power consumption Complex fabrication IJ07, IJ10 magnet electro- a permanent magnet, displacing Many ink types can be used Permanent magnetic material such as magnetic ink and causing drop ejection. Fast operation Neodymium Iron Boron (NdFeB) Rare earth magnets with a field High efficiency required. strength around 1 Tesla can be Easy extension from single High local currents required used. Examples are: Samarium nozzles to pagewidth print Copper metalization should be used Cobalt (SaCo) and magnetic heads for long electromigration lifetime and materials in the neodymium iron low resistivity boron family (NdFeB, Pigmented inks are usually infeasible NdDyFeBNb, NdDyFeB, etc) Operating temperature limited to the Curie temperature (around 540 K) Soft magnetic A solenoid induced a magnetic Low power consumption Complex fabrication IJ01, IJ05, IJ08, IJ10 core electro- field in a soft magnetic core or Many ink types can be used Materials not usually present in a IJ12, IJ14, IJ15, IJ17 magnetic yoke fabricated from a ferrous Fast operation CMOS fab such as NiFe, CoNiFe, or material such as electroplated iron High efficiency CoFe are required alloys such as CoNiFe [1], CoFe, Easy extension from single High local currents required or NiFe alloys. Typically, the soft nozzles to pagewidth print Copper metalization should be used magnetic material is in two parts, heads for long electromigration lifetime and which are normally held apart by low resistivity a spring. When the solenoid is Electroplating is required actuated, the two parts attract, High saturation flux density is displacing the ink, required (2.0-2.1 T is achievable with CoNiFe [1]) Magnetic The Lorenz force acting on a Low power consumption Force acts as a twisting motion IJ06, IJ11, IJ13, IJ16 Lorenz force current carrying wire in a Many ink types can be used Typically, only a quarter of the magnetic field is utilized. Fast operation solenoid length provides force in a This allows the magnetic field to High efficiency useful direction be supplied externally to the print Easy extension from single High local currents required head, for example with rare earth nozzles to pagewidth print Copper metalization should be used permanent magnets. heads for long electromigration lifetime and Only the current carrying wire low resistivity need be fabricated on the print- Pigmented inks are usually infeasible head, simplifying materials requirements. Magneto- The actuator uses the giant Many ink types can be used Force acts as a twisting motion Fischenbeck, U.S. Pat. striction magnetostrictive effect of Fast operation Unusual materials such as Terfenol-D No. 4,032,929 materials such as Terfenol-D (an Easy extension from single are required IJ25 alloy of terbium, dysprosium and nozzles to pagewidth print High local currents required iron developed at the Naval heads Copper metalization should be used Ordnance Laboratory, hence Ter- High force is available for long electromigration lifetime and Fe-NOL). For best efficiency, the low resistivity actuator should be pre-stressed to Pre-stressing may be required approx. 8 MPa. Surface tension Ink under positive pressure is held Low power consumption Requires supplementary force to effect Silverbrook, EP 0771 reduction in a nozzle by surface tension. Simple construction drop separation 658 A2 and related The surface tension of the ink is No unusual materials Requires special ink surfactants patent applications reduced below the bubble required in fabrication Speed may be limited by surfactant threshold, causing the ink to High efficiency properties egress from the nozzle. Easy extension from single nozzles to pagewidth print heads Viscosity The ink viscosity is locally Simple construction Requires supplementary force to effect Silverbrook, EP 0771 reduction reduced to select which drops are No unusual materials drop separation 658 A2 and related to be ejected. A viscosity required in fabrication Requires special ink viscosity patent applications reduction can be achieved Easy extension from single properties electrothermally with most inks, nozzles to pagewidth print High speed is difficult to achieve but special inks can be engineered heads Requires oscillating ink pressure for a 100:1 viscosity reduction. A high temperature difference (typically 80 degrees) is required Acoustic An acoustic wave is generated and Can operate without a Complex drive circuitry 1993 Hadimioglu et focussed upon the drop ejection nozzle plate Complex fabrication al, EUP 550,192 region. Low efficiency 1993 Elrod et al, EUP Poor control of drop position 572,220 Poor control of drop volume Thermoelastic An actuator which relies upon Low power consumption Efficient aqueous operation requires a IJ03, IJ09, IJ17, IJ18 bend actuator differential thermal expansion Many ink types can be used thermal insulator on the hot side IJ19, IJ20, IJ21, IJ22 upon Joule heating is used. Simple pLanar fabrication Corrosion prevention can be difficult IJ23, IJ24, IJ27, IJ28 Small integrated circuit area Pigmented inks may be infeasible, as IJ29, IJ30, IJ31, IJ32 required for each actuator pigment particles may jam the bend IJ33, IJ34, IJ35, IJ36 Fast operation actuator IJ37, IJ38 ,IJ39, IJ40 High efficiency IJ41 CMOS compatible voltages and currents Standard MEMS processes can be used Easy extension from single nozzles to pagewidth print heads High CTE A material with a very high High force can be generated Requires special material (e.g. PTFE) IJ09, IJ17, IJ18, IJ20 thermoelastic coefficient of thermal expansion PTFE is a candidate for low Requires a PTFE deposition process, IJ21, IJ22, IJ23, IJ24 actuator (CTE) such as dielectric constant insulation which is not yet standard in ULSI fabs IJ27, IJ28, IJ29, IJ30 polytetrafluoroethylene (PTFE) is in ULSI PTFE deposition cannot be followed IJ31, IJ42, IJ43, IJ44 used. As high GTE materials are Very low power with high temperature (above 350° C.) usually non-conductive, a heater consumption processing fabricated from a conductive Many ink types can be used Pigmented inks may be infeasible, as material is incorporated. A 50 μm Simple planar fabrication pigment particles may jam the bend long PTFE bend actuator with Small integrated circuit area actuator polysilicon heater and 15 mW required for each actuator power input can provide 180 μN Fast operation force and 10 μm deflection. High efficiency Actuator motions include: CMOS compatible voltages Bend and currents Push Easy extension from single Buckle nozzles to pagewidth print Rotate heads Conductive A polymer with a high coefficient High force can be generated Requires special materials IJ24 polymer of thermal expansion (such as Very low power development (High CTE conductive thermoelastic PTFE) is doped with conducting consumption polymer) actuator substances to increase its Many ink types can be used Requires a PTFE deposition process, conductivity to about 3 orders of Simple planar fabrication which is not yet standard in ULSI fabs magnitude below that of copper. Small integrated circuit area PTFE deposition cannot be followed The conducting polymer expands required for each actuator with high temperature (above 350° C.) when resistively heated. Fast operation processing Examples of conducting dopants High efficiency Evaporation and CVD deposition include: CMOS compatible voltages techniques cannot be used Carbon nanotubes and currents Pigmented inks may be infeasible, as Metal fibers Easy extension from single pigment particles may jam the bend Conductive polymers such as nozzles to pagewidth print actuator doped polythiophene heads Carbon granules Shape memory A shape memory alloy such as High force is available Fatigue limits maximum number of IJ26 alloy TiNi (also known as Nitinol- (stresses of hundreds of cycles Nickel Titanium alloy developed MPa) Low strain (1%) is required to extend at the Naval Ordnance Large strain is available fatigue resistance Laboratory) is thermally switched (more than 3%) Cycle rate limited by heat removal between its weak martensitic state High corrosion resistance Requires unusual materials (TiNi) and its high stiffness austenic Simple construction The latent heat of transformation must state. The shape of the actuator in Easy extension from single be provided its martensitic state is deformed nozzles to pagewidth print High current operation relative to the austenic shape. The heads Requires pre-stressing to distort the shape change causes ejection of a Low voltage operation martensitic state drop. Linear Magnetic Linear magnetic actuators include Linear Magnetic actuators Requires unusual semiconductor IJ12 Actuator the Linear Induction Actuator can be constructed with high materials such as soft magnetic alloys (LIA), Linear Permanent Magnet thrust, long travel, and high (e.g. CoNiFe [1]) Synchronous Actuator (LPMSA), efficiency using planar Some varieties also require permanent Linear Reluctance Synchronous semiconductor fabrication magnetic materials such as Actuator (LRSA), Linear techniques Neodymium iron boron (NdFeB) Switched Reluctance Actuator Long actuator travel is Requires complex multi-phase drive (LSRA), and the Linear Stepper available circuitry Actuator (LSA). Medium force is available High current operation Low voltage operation Basic operation mode Operational mode Description Advantages Disadvantages Examples Actuator This is the simplest mode of Simple operation Drop repetition rate is usually limited Thermal inkjet directly pushes operation: the actuator directly No external fields required to less than 10 KHz. However, this is Piezoelectric inkjet ink supplies sufficient kinetic energy Satellite drops can be not fundamental to the method, but is IJ01, IJ02, IJ03, IJ04 to expel the drop. The drop must avoided if drop velocity is related to the refill method normally IJ05, IJ06, IJ07, IJ09 have a sufficient velocity to less than 4 m/s used IJ11, IJ12, IJ14, IJ16 overcome the surface tension. Can be efficient, depending All of the drop kinetic energy must be IJ20, IJ22, IJ23, IJ24 upon the actuator used provided by the actuator IJ25, IJ26, IJ27, IJ28 Satellite drops usually form if drop IJ29, IJ30, IJ31, IJ32 velocity is greater than 4.5 m/s IJ33, IJ34, IJ35, IJ36 IJ37, IJ38, IJ39, IJ40 IJ41, IJ42, IJ43, IJ44 Proximity The drops to be printed are Very simple print head Requires close proximity between the Silverbrook, EP 0771 selected by some manner (e.g. fabrication can be used print head and the print media or 658 A2 and related thermally induced surface tension The drop selection means transfer roller patent applications reduction of pressurized ink), does not need to provide the May require two print heads printing Selected drops are separated from energy required to separate alternate rows of the image the ink in the nozzle by contact the drop from the nozzle Monolithic color print heads are with the print medium or a difficult transfer roller. Electrostatic The drops to be printed are Very simple print head Requires very high electrostatic field Silverbrook, EP 0771 pull on ink selected by some manner (e.g. fabrication can be used Electrostatic field for small nozzle 658 A2 and related thermally induced surface tension The drop selection means sizes is above air breakdown patent applications reduction of pressurized ink), does not need to provide the Electrostatic field may attract dust Tone-Jet Selected drops are separated from energy required to separate the ink in the nozzle by a strong the drop from the nozzle electric field. Magnetic pull The drops to be printed are Very simple print head Requires magnetic ink Silverbrook, EP 0771 on ink selected by some manner (e.g. fabrication can be used Ink colors other than black are 658 A2 and related thermally induced surface tension The drop selection means difficult patent applications reduction of pressurized ink), does not need to provide the Requires very high magnetic fields Selected drops are separated from energy required to separate the ink in the nozzle by a strong the drop from the nozzle magnetic field acting on the magnetic ink. Shutter The actuator moves a shutter to High speed (>50 KHz) Moving parts are required IJ13, IJ17, IJ21 block ink flow to the nozzle. The operation can be achieved Requires ink pressure modulator ink pressure is pulsed at a due to reduced refill time Friction and wear must be considered multiple of the drop ejection Drop timing can be very Stiction is possible frequency. accurate The actuator energy can be very low Shuttered grill The actuator moves a shutter to Actuators with small travel Moving parts are required IJ08, IJI5, IJ18, IJ19 block ink flow through a grill to can be used Requires ink pressure modulator the nozzle. The shutter movement Actuators with small force Friction and wear must be considered need only be equal to the width of can be used Stiction is possible the grill holes. High speed (>50 KHz) operation can be achieved Pulsed magnetic A pulsed magnetic field attracts Extremely low energy Requires an external pulsed magnetic IJ10 pull on ink an ‘ink pusher’ at the drop operation is possible field pusher ejection frequency. An actuator No heat dissipation Requires special materials for both the controls a catch, which prevents problems actuator and the ink pusher the ink pusher from moving when Complex construction a drop is not to be ejected. Auxiliary mechanism (applied to all nozzles) Auxiliary Mechanism Description Advantages Disadvantages Examples None The actuator directly fires the ink Simplicity of construction Drop ejection energy must be supplied Most inkjets, drop, and there is no external field Simplicity of operation by individual nozzle actuator including piezoelectric or other mechanism required. Small physical size and thermal bubble. IJ01-IJ07, IJ09, IJ11 IJ12, IJ14, IJ20, IJ22 IJ23-IJ45 Oscillating ink The ink pressure oscillates, Oscillating ink pressure can Requires external ink pressure Silverbrook, EP 0771 pressure providing much of the drop provide a refill pulse, oscillator 658 A2 and related (including ejection energy. The actuator allowing higher operating Ink pressure phase and amplitude must patent applications acoustic selects which drops are to be fired speed be carefully controlled IJ08, IJ13, IJ15, IJ17 stimulation) by selectively blocking or The actuators may operate Acoustic reflections in the ink IJ18, IJ19, IJ21 enabling nozzles. The ink pressure with much lower energy chamber must be designed for oscillation may be achieved by Acoustic lenses can be used vibrating the print head, or to focus the sound on the preferably by an actuator in the nozzles ink supply. Media The print head is placed in close Low power Precision assembly required Silverbrook, EP 0771 proximity proximity to the print medium. High accuracy Paper fibers may cause problems 658 A2 and related Selected drops protrude from the Simple print head Cannot print on rough substrates patent applications print head further than unselected construction drops, and contact the print medium. The drop soaks into the medium fast enough to cause drop separation. Transfer roller Drops are printed to a transfer High accuracy Bulky Silverbrook, EP 0771 roller instead of straight to the Wide range of print Expensive 658 A2 and related print medium. A transfer roller substrates can be used Complex construction patent applications can also be used for proximity Ink can be dried on the Tektronix hot melt drop separation. transfer roller piezoelectric inkjet Any of the IJ series Electrostatic An electric field is used to Low power Field strength required for separation Silverbrook, EP 0771 accelerate selected drops towards Simple print head of small drops is near or above air 658 A2 and related the print medium. construction breakdown patent applications Tone-Jet Direct magnetic A magnetic field is used to Low power Requires magnetic ink Silverbrook, EP 0771 field accelerate selected drops of Simple print head Requires strong magnetic field 658 A2 and related magnetic ink towards the print construction patent applications medium. Cross magnetic The print head is placed in a Does not require magnetic Requires external magnet IJ06, IJ16 field constant magnetic field. The materials to be integrated in Current densities may be high, Lorenz force in a current carrying the print head resulting in electromigration problems wire is used to move the actuator. manufacturing process Pulsed magnetic A pulsed magnetic field is used to Very low power operation is Complex print head construction IJ10 field cyclically attract a paddle, which possible Magnetic materials required in print pushes on the ink. A small Small print head size head actuator moves a catch, which selectively prevents the paddle from moving. Actuator amplification or modification method Actuator amplification Description Advantages Disadvantages Examples None No actuator mechanical Operational simplicity Many actuator mechanisms have Thermal Bubble Inkjet amplification is used. The actuator insufficient travel, or insufficient IJ01, IJ02, IJ06, IJ07 directly drives the drop ejection force, to efficiently drive the drop IJ16, IJ25, IJ26 process. ejection process Differential An actuator material expands Provides greater travel in a High stresses are involved Piezoelectric expansion bend more on one side than on the reduced print head area Care must be taken that the materials IJ03, IJ09, IJ17-IJ24 actuator other. The expansion may be The bend actuator converts do not delaminate IJ27, IJ29-IJ39, IJ42, thermal, piezoelectric, a high force low travel Residual bend resulting from high IJ43, IJ44 magnetostrictive, or other actuator mechanism to high temperature or high stress during mechanism, travel, lower force formation mechanism. Transient bend A trilayer bend actuator where the Very good temperature High stresses are involved IJ40, IJ41 actuator two outside layers are identical. stability Care must be taken that the materials This cancels bend due to ambient High speed, as a new drop do not delaminate temperature and residual stress. can be fired before heat The actuator only responds to dissipates transient heating of one side or the Cancels residual stress of other. formation Actuator stack A series of thin actuators are Increased travel Increased fabrication complexity Some piezoelectric stacked. This can be appropriate Reduced drive voltage Increased possibility of short circuits ink jets where actuators require high due to pinholes IJ04 electric field strength, such as electrostatic and piezoelectric actuators. Multiple Multiple smaller actuators are Increases the force available Actuator forces may not add linearly, IJ12, IJ13, IJ18, IJ20 actuators used simultaneously to move the from an actuator reducing efficiency IJ22, IJ28, IJ42, IJ43 ink. Each actuator need provide Multiple actuators can be only a portion of the force positioned to control ink required. flow accurately Linear Spring A linear spring is used to Matches low travel actuator Requires print head area for the spring IJ15 transform a motion with small with higher travel travel and high force into a longer requirements travel, lower force motion. Non-contact method of motion transformation Reverse spring The actuator loads a spring. When Better coupling to the ink Fabrication complexity IJ05, IJ11 the actuator is turned off, the High stress in the spring spring releases. This can reverse the force/distance curve of the actuator to make it compatible with the force/time requirements of the drop ejection. Coiled actuator A bend actuator is coiled to Increases travel Generally restricted to planar IJ17, IJ21, IJ34, IJ35 provide greater travel in a reduced Reduces integrated circuit implementations due to extreme integrated circuit area. area fabrication difficulty in other Planar implementations are orientations. relatively easy to fabricate. Flexure bend A bend actuator has a small Simple means of increasing Care must be taken not to exceed the IJ10, IJ19, IJ33 actuator region near the fixture point, travel of a bend actuator elastic limit in the flexure area which flexes much more readily Stress distribution is very uneven than the remainder of the actuator. Difficult to accurately model with The actuator flexing is effectively finite element analysis converted from an even coiling to an angular bend, resulting in greater travel of the actuator tip. Gears Gears can be used to increase Low force, low travel Moving parts are required IJ13 travel at the expense of duration. actuators can be used Several actuator cycles are required Circular gears, rack and pinion, Can be fabricated using More complex drive electronics ratchets, and other gearing standard surface MEMS Complex construction methods can be used. processes Friction, friction, and wear are possible Catch The actuator controls a small Very low actuator energy Complex construction IJ10 catch. The catch either enables or Very small actuator size Requires external force disables movement of an ink Unsuitable for pigmented inks pusher that is controlled in a bulk manner. Buckle plate A buckle plate can be used to Very fast movement Must stay within elastic limits of the S. Hirata et al, “An change a slow actuator into a fast achievable materials for long device life Ink-jet Head . . .”, motion. It can also convert a high High stresses involved Proc. IEEE MEMS, force, low travel actuator into a Generally high power requirement Feb. 1996, pp 418- high travel, medium force motion. 423. IJ18, IJ27 Tapered A tapered magnetic pole can Linearizes the magnetic Complex construction IJ14 magnetic pole increase travel at the expense of force/distance curve force. Lever A lever and fulcrum is used to Matches low travel actuator High stress around the fulcrum IJ32, IJ36, IJ37 transform a motion with small with higher travel travel and high force into a requirements motion with longer travel and Fulcrum area has no linear lower force. The lever can also movement, and can be used reverse the direction of travel, for a fluid seal Rotary impeller The actuator is connected to a High mechanical advantage Complex construction IJ28 rotary impeller. A small angular The ratio of force to travel Unsuitable for pigmented inks deflection of the actuator results of the actuator can be in a rotation of the impeller vanes, matched to the nozzle which push the ink against requirements by varying the stationary vanes and out of the number of impeller vanes nozzle. Acoustic lens A refractive or diffractive (e.g. No moving parts Large area required 1993 Hadimioglu et zone plate) acoustic lens is used to Only relevant for acoustic ink jets al, EUP 550,192 concentrate sound waves. 1993 Elrod et al, EUP 572,220 Sharp A sharp point is used to Simple construction Difficult to fabricate using standard Tone-jet conductive concentrate an electrostatic field. VLSI processes for a surface ejecting point ink-jet Only relevant for electrostatic ink jets Actuator motion Actuator motion Description Advantages Disadvantages Examples Volume The volume of the actuator Simple construction in the High energy is typically required to Hewlett-Packard expansion changes, pushing the ink in all case of thermal ink jet achieve volume expansion. This leads Thermal Inkjet directions. to thermal stress, cavitation, and Canon Bubblejet kogation in thermal ink jet implementations Linear, normal The actuator moves in a direction Efficient coupling to ink High fabrication complexity may be IJ01, IJ02, IJ04, IJ07 to integrated normal to the print head surface. drops ejected normal to the required to achieve perpendicular IJ11, IJ14 circuit surface The nozzle is typically in the line surface motion of movement. Linear, parallel The actuator moves parallel to the Suitable for planar Fabrication complexity IJ12, IJ13, IJ15, IJ33, to integrated print head surface. Drop ejection fabrication Friction IJ34, IJ35, IJ36 circuit surface may still be normal to the surface. Stiction Membrane push An actuator with a high force but The effective area of the Fabrication complexity 1982 Howkins U.S. small area is used to push a stiff actuator becomes the Actuator size Pat. No. 4,459,601 membrane that is in contact with membrane area Difficulty of integration in a VLSI the ink. process Rotary The actuator causes the rotation of Rotary levers may be used Device complexity IJ05, IJ08, IJ13, IJ28 some element, such a grill or to increase travel May have friction at a pivot point impeller Small integrated circuit area requirements Bend The actuator bends when A very small change in Requires the actuator to be made from 1970 Kyser et al U.S. energized. This may be due to dimensions can be at least two distinct layers, or to have a Pat. No. 3,946,398 differential thermal expansion, converted to a large motion. thermal difference across the actuator 1973 Stemme U.S. piezoelectric expansion, Pat. No. 3,747,120 magnetostriction, or other form of IJ03, IJ09, IJ00, IJ19 relative dimensional change. IJ23, IJ24, IJ25, IJ29 IJ30, IJ31, IJ33, IJ34 IJ35 Swivel The actuator swivels around a Allows operation where the Inefficient coupling to the ink motion IJ06 central pivot. This motion is net linear force on the suitable where there are opposite paddle is zero forces applied to opposite sides of Small integrated circuit area the paddle, e.g. Lorenz force. requirements Straighten The actuator is normally bent, and Can be used with shape Requires careful balance of stresses to IJ26, IJ32 straightens when energized. memory alloys where the ensure that the quiescent bend is austenic phase is planar accurate Double bend The actuator bends in one One actuator can be used to Difficult to make the drops ejected by IJ36, IJ37, IJ38 direction when one element is power two nozzles. both bend directions identical. energized, and bends the other Reduced integrated circuit A small efficiency loss compared to way when another element is size. equivalent single bend actuators. energized. Not sensitive to ambient temperature Shear Energizing the actuator causes a Can increase the effective Not readily applicable to other 1985 Fishbeck U.S. shear motion in the actuator travel of piezoelectric actuator mechanisms Pat. No. 4,584,590 material, actuators Radial The actuator squeezes an ink Relatively easy to fabricate High force required 1970 Zoltan U.S. constriction reservoir, forcing ink from a single nozzles from glass Inefficient Pat. No. 3,683,212 constricted nozzle. tubing as macroscopic Difficult to integrate with VLSI structures processes Coil/uncoil A coiled actuator uncoils or coils Easy to fabricate as a planar Difficult to fabricate for non-planar IJ17, IJ21, IJ34, IJ35 more tightly. The motion of the VLSI process devices free end of the actuator ejects the Small area required, Poor out-of-plane stiffness ink. therefore low cost Bow The actuator bows (or buckles) in Can increase the speed of Maximum travel is constrained IJ16, IJ18, IJ27 the middle when energized. travel High force required Mechanically rigid Push-Pull Two actuators control a shutter. The structure is pinned at Not readily suitable for inkjets which IJ18 One actuator pulls the shutter, and both ends, so has a high out- directly push the ink the other pushes it. of-plane rigidity Curl inwards A set of actuators curl inwards to Good fluid flow to the Design complexity IJ20, IJ42 reduce the volume of ink that they region behind the actuator enclose, increases efficiency Curl outwards A set of actuators curl outwards, Relatively simple Relatively large integrated circuit area IJ43 pressurizing ink in a chamber construction surrounding the actuators, and expelling ink from a nozzle in the chamber. Iris Multiple vanes enclose a volume High efficiency High fabrication complexity IJ22 of ink. These simultaneously Small integrated circuit area Not suitable for pigmented inks rotate, reducing the volume between the vanes. Acoustic The actuator vibrates at a high The actuator can be Large area required for efficient 1993 Hadimioglu et vibration frequency. physically distant from the operation at useful frequencies al, EUP 550,192 ink Acoustic coupling and crosstalk 1993 Elrod et al, EUP Complex drive circuitry 572,220 Poor control of drop volume and position None In various ink jet designs the No moving parts Various other tradeoffs are required to Silverbrook, EP 0771 actuator does not move. eliminate moving parts 658 A2 and related patent applications Tone-jet Nozzle refill method Nozzle refill method Description Advantages Disadvantages Examples Surface tension After the actuator is energized, it Fabrication simplicity Low speed Thermal inkjet typically returns rapidly to its Operational simplicity Surface tension force relatively small Piezoelectric inkjet normal position. This rapid return compared to actuator force IJ01-IJ07, IJ10-IJ14 sucks in air through the nozzle Long refill time usually dominates the IJ16, IJ20, IJ22-IJ45 opening. The ink surface tension total repetition rate at the nozzle then exerts a small force restoring the meniscus to a minimum area. Shuttered Ink to the nozzle chamber is High speed Requires common ink pressure IJ08, IJ13, IJ15, IJ17 oscillating ink provided at a pressure that Low actuator energy, as the oscillator IJ18, IJ19, IJ21 pressure oscillates at twice the drop actuator need only open or May not be suitable for pigmented ejection frequency. When a drop close the shutter, instead of inks is to be ejected, the shutter is ejecting the ink drop opened for 3 half cycles: drop ejection, actuator return, and refill. Refill actuator After the main actuator has High speed, as the nozzle is Requires two independent actuators IJ09 ejected a drop a second (refill) actively refilled per nozzle actuator is energized. The refill actuator pushes ink into the nozzle chamber. The refill actuator returns slowly, to prevent its return from emptying the chamber again. Positive ink The ink is held a slight positive High refill rate, therefore a Surface spill must be prevented Silverbrook, EP 0771 pressure pressure. After the ink drop is high drop repetition rate is Highly hydrophobic print head 658 A2 and related ejected, the nozzle chamber fills possible surfaces are required patent applications quickly as surface tension and ink Alternative for: pressure both operate to refill the IJ01-IJ07, IJ10-IJ14 nozzle. IJ16, IJ20, IJ22-IJ45 Method of restricting back-flow through inlet Inlet back-flow restriction method Description Advantages Disadvantages Examples Long inlet The ink inlet channel to the nozzle Design simplicity Restricts refill rate Thermal inkjet channel chamber is made long and Operational simplicity May result in a relatively large Piezoelectric inkjet relatively narrow, relying on Reduces crosstalk integrated circuit area IJ42, IJ43 viscous drag to reduce inlet back- Only partially effective flow. Positive ink The ink is under a positive Drop selection and Requires a method (such as a nozzle Silverbrook, EP 0771 pressure pressure, so that in the quiescent separation forces can be rim or effective hydrophobizing, or 658 A2 and related state some of the ink drop already reduced both) to prevent flooding of the patent applications protrudes from the nozzle. Fast refill time ejection surface of the print head. Possible operation of This reduces the pressure in the the following: nozzle chamber which is required IJ01-IJ07, IJ09-IJ12 to eject a certain volume of ink. IJ14, IJ16, IJ20, IJ22, The reduction in chamber IJ23-IJ34, IJ36-IJ41 pressure results in a reduction in IJ44 ink pushed out through the inlet. Baffle One or more baffles are placed in The refill rate is not as Design complexity HP Thermal Ink Jet the inlet ink flow. When the restricted as the long inlet May increase fabrication complexity Tektronix actuator is energized, the rapid ink method. (e.g. Tektronix hot melt Piezoelectric piezoelectric ink jet movement creates eddies which Reduces crosstalk print heads). restrict the flow through the inlet. The slower refill process is unrestricted, and does not result in eddies. Flexible flap In this method recently disclosed Significantly reduces back- Not applicable to most inkjet Canon restricts inlet by Canon, the expanding actuator flow for edge-shooter configurations (bubble) pushes on a flexible flap thermal ink jet devices Increased fabrication complexity that restricts the inlet. Inelastic deformation of polymer flap results in creep over extended use Inlet filter A filter is located between the ink Additional advantage of ink Restricts refill rate IJ04, IJ12, IJ24, IJ27 inlet and the nozzle chamber. The filtration May result in complex construction IJ29, IJ30 filter has a multitude of small Ink filter may be fabricated holes or slots, restricting ink flow, with no additional process The filter also removes particles steps which may block the nozzle. Small inlet The ink inlet channel to the nozzle Design simplicity Restricts refill rate IJ02, IJ37, IJ44 compared to chamber has a substantially May result in a relatively large nozzle smaller cross section than that of integrated circuit area the nozzle , resulting in easier ink Only partially effective egress out of the nozzle than out of the inlet. Inlet shutter A secondary actuator controls the Increases speed of the ink- Requires separate refill actuator and IJ09 position of a shutter, closing off jet print head operation drive circuit the ink inlet when the main actuator is energized. The inlet is The method avoids the problem of Back-flow problem is Requires careful design to minimize IJ01, IJ03, IJ05, IJ06 located behind inlet back-flow by arranging the eliminated the negative pressure behind the IJ07, IJ10, IJ11, IJ14 the ink-pushing ink-pushing surface of the paddle IJ16, IJ22, IJ23, IJ25 surface actuator between the inlet and the IJ28, IJ31, IJ32, IJ33 nozzle. IJ34, IJ35, IJ36, IJ39 IJ40, IJ41 Part of the The actuator and a wall of the ink Significant reductions in Small increase in fabrication IJ07, IJ20, IJ26, IJ38 actuator moves chamber are arranged so that the back-flow can be achieved complexity to shut off the motion of the actuator closes off Compact designs possible inlet the inlet. Nozzle actuator In some configurations of ink jet, Ink back-flow problem is None related to ink back-flow on Silverbrook, EP 0771 does not result there is no expansion or eliminated actuation 658 A2 and related in ink back-flow movement of an actuator which patent applications may cause ink back-flow through Valve-jet the inlet. Tone-jet IJ08, IJ13, IJ15, IJ17 IJ18, IJ19, IJ21 Nozzle Clearing Method Nozzle Clearing method Description Advantages Disadvantages Examples Normal nozzle All of the nozzles are fired No added complexity on the May not be sufficient to displace dried Most ink jet systems firing periodically, before the ink has a print head ink IJ01-IJ07, IJ09-IJ12 chance to dry. When not in use IJ14, IJ16, IJ20, IJ22 the nozzles are sealed (capped) IJ23-IJ34, IJ36-IJ45 against air. The nozzle firing is usually performed during a special clearing cycle, after first moving the print head to a cleaning station. Extra power to In systems which heat the ink, but Can be highly effective if Requires higher drive voltage for Silverbrook, EP 0771 ink heater do not boil it under normal the heater is adjacent to the clearing 658 A2 and related situations, nozzle clearing can be nozzle May require larger drive transistors patent applications achieved by over-powering the heater and boiling ink at the nozzle. Rapid The actuator is fired in rapid Does not require extra drive Effectiveness depends substantially May be used with: succession of succession. In some circuits on the print head upon the configuration of the inkjet IJ01-IJ07, IJ09-IJ11 actuator pulses configurations, this may cause Can be readily controlled nozzle IJ14, IJ16, IJ20, IJ22 heat build-up at the nozzle which and initiated by digital logic IJ23-IJ25, IJ27-IJ34 boils the ink, clearing the nozzle. IJ36-IJ45 In other situations, it may cause sufficient vibrations to dislodge clogged nozzles. Extra power to Where an actuator is not normally A simple solution where Not suitable where there is a hard limit May be used with: ink pushing driven to the limit of its motion, applicable to actuator movement IJ03, IJ09, IJ16, IJ20 actuator nozzle clearing may be assisted by IJ23, IJ24, IJ25, IJ27 providing an enhanced drive IJ29, IJ30, IJ31, IJ32 signal to the actuator. IJ39, IJ40, IJ41, IJ42 IJ43, IJ44, IJ45 Acoustic An ultrasonic wave is applied to A high nozzle clearing High implementation cost if system IJ08, IJ13, IJ15, IJ17 resonance the ink chamber. This wave is of capability can be achieved does not already include an acoustic IJ18, IJ19, IJ21 an appropriate amplitude and May be implemented at very actuator frequency to cause sufficient force low cost in systems which at the nozzle to clear blockages, already include acoustic This is easiest to achieve if the actuators ultrasonic wave is at a resonant frequency of the ink cavity. Nozzle clearing A microfabricated plate is pushed Can clear severely clogged Accurate mechanical alignment is Silverbrook, EP 0771 plate against the nozzles. The plate has nozzles required 658 A2 and related a post for every nozzle. The array Moving parts are required patent applications of posts There is risk of damage to the nozzles Accurate fabrication is required Ink pressure The pressure of the ink is May be effective where Requires pressure pump or other May be used with all pulse temporarily increased so that ink other methods cannot be pressure actuator IJ series ink jets streams from all of the nozzles. used Expensive This may be used in conjunction Wasteful of ink with actuator energizing. Print head wiper A flexible ‘blade’ is wiped across Effective for planar print Difficult to use if print head surface is Many ink jet systems the print head surface. The blade head surfaces non-planar or very fragile is usually fabricated from a Low cost Requires mechanical parts flexible polymer, e.g. rubber or Blade can wear out in high volume synthetic elastomer. print systems Separate ink A separate heater is provided at Can be effective where Fabrication complexity Can be used with boiling heater the nozzle although the normal other nozzle clearing many IJ series ink jets drop e-ection mechanism does methods cannot be used not require it. The heaters do not Can be implemented at no require individual drive circuits, additional cost in some as many nozzles can be cleared inkjet configurations simultaneously, and no imaging is required. Nozzle plate construction Nozzle plate construction Description Advantages Disadvantages Examples Electroformed A nozzle plate is separately Fabrication simplicity High temperatures and pressures are Hewlett Packard nickel fabricated from electroformed required to bond nozzle plate Thermal Inkjet nickel, and bonded to the print Minimum thickness constraints head integrated circuit. Differential thermal expansion Laser ablated or Individual nozzle holes are No masks required Each hole must be individually formed Canon Bubblejet drilled polymer ablated by an intense UV laser in Can be quite fast Special equipment required 1988 Sercel et al., a nozzle plate, which is typically a Some control over nozzle Slow where there are many thousands SPIE, Vol. 998 polymer such as polyimide or profile is possible of nozzles per print head Excimer Beam polysulphone Equipment required is May produce thin burrs at exit holes Applications, pp. 76- relatively low cost 83 1993 Watanabe et al., U.S. Pat. No. 5,208,604 Silicon micro- A separate nozzle plate is High accuracy is attainable Two part construction K. Bean, IEEE machined micromachined from single High cost Transactions on crystal silicon, and bonded to the Requires precision alignment Electron Devices, Vol. print head wafer. Nozzles may be clogged by adhesive ED-25, No. 10, 1978, pp 1185-1195 Xerox 1990 Hawkins et al., U.S. Pat. No. 4,899,181 Glass capillaries Fine glass capillaries are drawn No expensive equipment Very small nozzle sizes are difficult to 1970 Zoltan U.S. Pat. from glass tubing. This method required form No. 3,683,212 has been used for making Simple to make single Not suited for mass production individual nozzles, but is difficult nozzles to use for bulk manufacturing of print heads with thousands of nozzles. Monolithic, The nozzle plate is deposited as a High accuracy (<1 μm) Requires sacrificial layer under the Silverbrook, EP 0771 surface micro- layer using standard VLSI Monolithic nozzle plate to form the nozzle 658 A2 and related machined using deposition techniques. Nozzles Low cost chamber patent applications VLSI are etched in the nozzle plate Existing processes can be Surface may be fragile to the touch IJ01, IJ02, IJ04, IJ11 lithographic using VLSI lithography and used IJ12, IJ17, IJ18, IJ20 processes etching. IJ22, IJ24, IJ27, IJ28 IJ29, IJ30, IJ31, IJ32 IJ33, IJ34, IJ36, IJ37 IJ38, IJ39, IJ40, IJ41 IJ42, IJ43, IJ44 Monolithic, The nozzle plate is a buried etch High accuracy (<1 μm) Requires long etch times IJ03, IJ05, IJ06, IJ07 etched through stop in the wafer. Nozzle Monolithic Requires a support wafer IJ08, IJ09, IJ10, IJ13 substrate chambers are etched in the front Low cost IJ14, IJ15, IJ16, IJ19 of the wafer, and the wafer is No differential expansion IJ21, IJ23, IJ25, IJ26 thinned from the back side. Nozzles are then etched in the etch stop layer. No nozzle plate Various methods have been tried No nozzles to become Difficult to control drop position Ricoh 1995 Sekiya et to eliminate the nozzles entirely, clogged accurately al U.S. Pat. No. to prevent nozzle clogging. These Crosstalk problems 5,412,413 1993 include thermal bubble Hadimioglu et al EUP mechanisms and acoustic lens 550,192 1993 Elrod et mechanisms al EUP 572,220 Trough Each drop ejector has a trough Reduced manufacturing Drop firing direction is sensitive to IJ35 through which a paddle moves, complexity wicking. There is no nozzle plate. Monolithic Nozzle slit The elimination of nozzle holes No nozzles to become Difficult to control drop position 1989 Saito et al U.S. instead of and replacement by a slit clogged accurately Pat. No. 4,799,068 individual encompassing many actuator Crosstalk problems nozzles positions reduces nozzle clogging, but increases crosstalk due to ink surface waves Drop ejection direction Ejection direction Description Advantages Disadvantages Examples Edge Ink flow is along the surface of Simple construction Nozzles limited to edge Canon Bubblejet 1979 (‘edge shooter’) the integrated circuit, and ink No silicon etching required High resolution is difficult Endo et al GB patent drops are ejected from the Good heat sinking via Fast color printing requires one print 2,007,162 integrated circuit edge. substrate head per color Xerox heater-in-pit Mechanically strong 1990 Hawkins et al Ease of integrated circuit U.S. Pat. No. handing 4,899,181 Tone-jet Surface Ink flow is along the surface of No bulk silicon etching Maximum ink flow is severely Hewlett-Packard TIJ (‘roof shooter’) the integrated circuit, and ink required restricted 1982 Vaught et al drops are ejected from the Silicon can make an U.S. Pat. No. integrated circuit surface, normal effective heat sink 4,490,728 IJ02, IJ11, to the plane of the integrated Mechanical strength IJ12, IJ20 IJ22 circuit. Through Ink flow is through the integrated High ink flow Requires bulk silicon etching Silverbrook, EP 0771 integrated circuit, and ink drops are ejected Suitable for pagewidth print 658 A2 and related circuit, forward from the front surface of the High nozzle packing density patent applications (‘up shooter’) integrated circuit, therefore low manufacturing IJ04, IJ17, IJ18, IJ24 cost IJ27-IJ45 Through Ink flow is through the integrated High ink flow Requires wafer thinning IJ01, IJ03, IJ05, IJ06 integrated circuit, and ink drops are ejected Suitable for pagewidth print Requires special handling during IJ07, IJ08, IJ09, IJ10 circuit, reverse from the rear surface of the High nozzle packing density manufacture IJ13, IJ14, IJ15, IJ16 (‘down integrated circuit. therefore low manufacturing IJ19, IJ21, IJ23, IJ25 shooter’) cost IJ26 Through Ink flow is through the actuator, Suitable for piezoelectric Pagewidth print heads require several Epson Stylus actuator which is not fabricated as part of print heads thousand connections to drive circuits Tektronix hot melt the same substrate as the drive Cannot be manufactured in standard piezoelectric ink jets transistors. CMOS fabs Complex assembly required Ink type Ink type Description Advantages Disadvantages Examples Aqueous, dye Water based ink which typically Environmentally friendly Slow drying Most existing inkjets contains: water, dye, surfactant, No odor Corrosive A11 IJ series ink jets humectant, and biocide. Bleeds on paper Silverbrook, EP 0771 Modem ink dyes have high water- May strikethrough 658 A2 and related fastness, light fastness Cockles paper patent applications Aqueous, Water based ink which typically Environmentally friendly Slow drying IJ02, IJ04, IJ21, IJ26 pigment contains: water, pigment, No odor Corrosive IJ27, IJ30 surfactant, humectant, and Reduced bleed Pigment may clog nozzles Silverbrook, EP 0771 biocide. Reduced wicking Pigment may clog actuator 658 A2 and related Pigments have an advantage in Reduced strikethrough mechanisms patent applications reduced bleed, wicking and Cockles paper Piezoelectric ink-jets strikethrough. Thermal ink jets (with significant restrictions) Methyl Ethyl MEK is a highly volatile solvent Very fast drying Odorous All IJ series ink jets Ketone (MEK) used for industrial printing on Prints on various substrates Flammable difficult surfaces such as such as metals and plastics aluminum cans. Alcohol Alcohol based inks can be used Fast drying Slight odor All IJ series ink jets (ethanol, 2- where the printer must operate at Operates at sub-freezing Flammable butanol, and temperatures below the freezing temperatures others) point of water. An example of this Reduced paper cockle is in-camera consumer Low cost photographic printing. Phase change The ink is solid at room No drying time-ink High viscosity Tektronix hot melt (hot melt) temperature, and is melted in the instantly freezes on the print Printed ink typically has a ‘waxy’ feel piezoelectric ink jets print head before jetting. Hot melt medium Printed pages may ‘block’ 1989 Nowak U.S. Pat. inks are usually wax based, with a Almost any print medium Ink temperature may be above the No. 4,820,346 melting point around 80° C. After can be used curie point of permanent magnets All IJ series ink jets jetting the ink freezes almost No paper cockle occurs Ink heaters consume power instantly upon contacting the print No wicking occurs Long warm-up time medium or a transfer roller. No bleed occurs No strikethrough occurs Oil Oil based inks are extensively High solubility medium for High viscosity: this is a significant All IJ series ink jets used in offset printing. They have some dyes limitation for use in inkjets, which advantages in improved Does not cockle paper usually require a low viscosity. Some characteristics on paper Does not wick through short chain and multi-branched oils (especially no wicking or cockle). paper have a sufficiently low viscosity. Oil soluble dies and pigments are Slow drying required. Microemulsion A microemulsion is a stable, self Stops ink bleed Viscosity higher than water All IJ series ink jets forming emulsion of oil, water, High dye solubility Cost is slightly higher than water and surfactant. The characteristic Water, oil, and amphiphilic based ink drop size is less than 100 nm, and soluble dies can be used High surfactant concentration required is determined by the preferred Can stabilize pigment (around 5%) curvature of the surfactant. suspensions Ink Jet Printing

A large number of new forms of ink jet printers have been developed to facilitate alternative ink jet technologies for the image processing and data distribution system. Various combinations of ink jet devices can be included in printer devices incorporated as part of the present invention. Australian Provisional Patent Applications relating to these ink jets which are specifically incorporated by cross reference. The serial numbers of respective corresponding U.S. patent applications are also provided for the sake of convenience.

U.S. Pat. No./ patent Australian application Provisional Ser. No. Number Filing Date Title and Filing Date PO8066 Jul. 15, 1997 Image Creation Method and  6,227,652 Apparatus (IJ01) (Jul. 10, 1998) PO8072 Jul. 15, 1997 Image Creation Method and  6,213,588 Apparatus (IJ02) (Jul. 10, 1998) PO8040 Jul. 15, 1997 Image Creation Method and  6,213,589 Apparatus (IJ03) (Jul. 10, 1998) PO8071 Jul. 15, 1997 Image Creation Method and  6,231,163 Apparatus (IJ04) (Jul. 10, 1998) PO8047 Jul. 15, 1997 Image Creation Method and  6,247,795 Apparatus (IJ05) (Jul. 10, 1998) PO8035 Jul. 15, 1997 Image Creation Method and  6,394,581 Apparatus (IJ06) (Jul. 10, 1998) PO8044 Jul. 15, 1997 Image Creation Method and  6,244,691 Apparatus (IJ07) (Jul. 10, 1998) PO8063 Jul. 15, 1997 Image Creation Method and  6,257,704 Apparatus (IJ08) (Jul. 10, 1998) PO8057 Jul. 15, 1997 Image Creation Method and  6,416,168 Apparatus (IJ09) (Jul. 10, 1998) PO8056 Jul. 15, 1997 Image Creation Method and  6,220,694 Apparatus (IJ10) (Jul. 10, 1998) PO8069 Jul. 15, 1997 Image Creation Method and  6,257,705 Apparatus (IJ11) (Jul. 10, 1998) PO8049 Jul. 15, 1997 Image Creation Method and  6,247,794 Apparatus (IJ12) (Jul. 10, 1998) PO8036 Jul. 15, 1997 Image Creation Method and  6,234,610 Apparatus (IJ13) (Jul. 10, 1998) PO8048 Jul. 15, 1997 Image Creation Method and  6,247,793 Apparatus (IJ14) (Jul. 10, 1998) PO8070 Jul. 15, 1997 Image Creation Method and  6,264,306 Apparatus (IJ15) (Jul. 10, 1998) PO8067 Jul. 15, 1997 Image Creation Method and  6,241,342 Apparatus (IJ16) (Jul. 10, 1998) PO8001 Jul. 15, 1997 Image Creation Method and  6,247,792 Apparatus (IJ17) (Jul. 10, 1998) PO8038 Jul. 15, 1997 Image Creation Method and  6,264,307 Apparatus (IJ18) (Jul. 10, 1998) PO8033 Jul. 15, 1997 Image Creation Method and  6,254,220 Apparatus (IJ19) (Jul. 10, 1998) PO8002 Jul. 15, 1997 Image Creation Method and  6,234,611 Apparatus (IJ20) (Jul. 10, 1998) PO8068 Jul. 15, 1997 Image Creation Method and  6,302,528 Apparatus (IJ21) (Jul. 10, 1998) PO8062 Jul. 15, 1997 Image Creation Method and  6,283,582 Apparatus (IJ22) (Jul. 10, 1998) PO8034 Jul. 15, 1997 Image Creation Method and  6,239,821 Apparatus (IJ23) (Jul. 10, 1998) PO8039 Jul. 15, 1997 Image Creation Method and  6,338,547 Apparatus (IJ24) (Jul. 10, 1998) PO8041 Jul. 15, 1997 Image Creation Method and  6,247,796 Apparatus (IJ25) (Jul. 10, 1998) PO8004 Jul. 15, 1997 Image Creation Method and 09/113,122 Apparatus (IJ26) (Jul. 10, 1998) PO8037 Jul. 15, 1997 Image Creation Method and  6,390,603 Apparatus (IJ27) (Jul. 10, 1998) PO8043 Jul. 15, 1997 Image Creation Method and  6,362,843 Apparatus (IJ28) (Jul. 10, 1998) PO8042 Jul. 15, 1997 Image Creation Method and  6,293,653 Apparatus (IJ29) (Jul. 10, 1998) PO8064 Jul. 15, 1997 Image Creation Method and  6,312,107 Apparatus (IJ30) (Jul. 10, 1998) PO9389 Sep. 23, Image Creation Method and  6,227,653 1997 Apparatus (IJ31) (Jul. 10, 1998) PO9391 Sep. 23, Image Creation Method and  6,234,609 1997 Apparatus (IJ32) (Jul. 10, 1998) PP0888 Dec. 12, Image Creation Method and  6,238,040 1997 Apparatus (IJ33) (Jul. 10, 1998) PP0891 Dec. 12, Image Creation Method and  6,188,415 1997 Apparatus (IJ34) (Jul. 10, 1998) PP0890 Dec. 12, Image Creation Method and  6,227,654 1997 Apparatus (IJ35) (Jul. 10, 1998) PP0873 Dec. 12, Image Creation Method and  6,209,989 1997 Apparatus (IJ36) (Jul. 10, 1998) PP0993 Dec. 12, Image Creation Method and  6,247,791 1997 Apparatus (IJ37) (Jul. 10, 1998) PP0890 Dec. 12, Image Creation Method and  6,336,710 1997 Apparatus (IJ38) (Jul. 10, 1998) PP1398 Jan. 19, Image Creation Method and  6,217,153 1998 Apparatus (IJ39) (Jul. 10, 1998) PP2592 Mar. 25, Image Creation Method and  6,416,167 1998 Apparatus (IJ40) (Jul. 10, 1998) PP2593 Mar. 25, Image Creation Method and  6,243,113 1998 Apparatus (IJ41) (Jul. 10, 1998) PP3991 Jun. 9, 1998 Image Creation Method and  6,283,581 Apparatus (IJ42) (Jul. 10, 1998) PP3987 Jun. 9, 1998 Image Creation Method and  6,247,790 Apparatus (IJ43) (Jul. 10, 1998) PP3985 Jun. 9, 1998 Image Creation Method and  6,260,953 Apparatus (IJ44) (Jul. 10, 1998) PP3983 Jun. 9, 1998 Image Creation Method and  6,267,469 Apparatus (IJ45) (Jul. 10, 1998) Ink Jet Manufacturing

Further, the present application may utilize advanced semiconductor fabrication techniques in the construction of large arrays of ink jet printers. Suitable manufacturing techniques are described in the following Australian provisional patent specifications incorporated here by cross-reference. The serial numbers of respective corresponding U.S. patent applications are also provided for the sake of convenience.

U.S. Pat. No./patent Australian application Provisional Filing Ser. No. and Number Date Title Filing Date PO7935 Jul. 15, A Method of Manufacture of  6,224,780 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM01) PO7936 Jul. 15, A Method of Manufacture of  6,235,212 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM02) PO7937 Jul. 15, A Method of Manufacture of  6,280,643 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM03) PO8061 Jul. 15, A Method of Manufacture of  6,284,147 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM04) PO8054 Jul. 15, A Method of Manufacture of  6,214,244 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM05) PO8065 Jul. 15, A Method of Manufacture of  6,071,750 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM06) PO8055 Jul. 15, A Method of Manufacture of  6,267,905 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM07) PO8053 Jul. 15, A Method of Manufacture of  6,251,298 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM08) PO8078 Jul. 15, A Method of Manufacture of  6,258,285 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM09) PO7933 Jul. 15, A Method of Manufacture of  6,225,138 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM10) PO7950 Jul. 15, A Method of Manufacture of  6,241,904 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM11) PO7949 Jul. 15, A Method of Manufacture of  6,299,786 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM12) PO8060 Jul. 15, A Method of Manufacture of 09/113,124 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM13) PO8059 Jul. 15, A Method of Manufacture of  6,231,773 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM14) PO8073 Jul. 15, A Method of Manufacture of  6,190,931 1997 an Image Creation Apparatus (Jul. 10, 19 98) (IJM15) PO8076 Jul. 15, A Method of Manufacture of  6,248,249 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM16) PO8075 Jul. 15, A Method of Manufacture of  6,290,862 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM17) PO8079 Jul. 15, A Method of Manufacture of  6,241,906 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM18) PO8050 Jul. 15, A Method of Manufacture of 09/113,116 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM19) PO8052 Jul. 15, A Method of Manufacture of  6,241,905 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM20) PO7948 Jul. 15, A Method of Manufacture of  6,451,216 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM21) PO7951 Jul. 15, A Method of Manufacture of  6,231,772 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM22) PO8074 Jul. 15, A Method of Manufacture of  6,274,056 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM23) PO7941 Jul. 15, A Method of Manufacture of  6,290,861 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM24) PO8077 Jul. 15, A Method of Manufacture of  6,248,248 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM25) PO8058 Jul. 15, A Method of Manufacture of  6,306,671 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM26) PO8051 Jul. 15, A Method of Manufacture of  6,331,258 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM27) PO8045 Jul. 15, A Method of Manufacture of  6,110,754 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM28) PO7952 Jul. 15, A Method of Manufacture of  6,294,101 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM29) PO8046 Jul. 15, A Method of Manufacture of  6,416,679 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM30) PO8503 Aug. 11, A Method of Manufacture of  6,264,849 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM30a) PO9390 Sep. 23, A Method of Manufacture of  6,254,793 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM31) PO9392 Sep. 23, A Method of Manufacture of  6,235,211 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM32) PP0889 Dec. 12, A Method of Manufacture of  6,235,211 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM35) PP0887 Dec. 12, A Method of Manufacture of  6,264,850 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM36) PP0882 Dec. 12, A Method of Manufacture of  6,258,284 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM37) PP0874 Dec. 12, A Method of Manufacture of  6,258,284 1997 an Image Creation Apparatus (Jul. 10, 1998) (IJM38) PP1396 Jan. 19, A Method of Manufacture of  6,228,668 1998 an Image Creation Apparatus (Jul. 10, 1998) (IJM39) PP2591 Mar. 25, A Method of Manufacture of  6,180,427 1998 an Image Creation Apparatus (Jul. 10, 1998) (IJM41) PP3989 Jun. 9, A Method of Manufacture of  6,171,875 1998 an Image Creation Apparatus (Jul. 10, 1998) (IJM40) PP3990 Jun. 9, A Method of Manufacture of  6,267,904 1998 an Image Creation Apparatus (Jul. 10, 1998) (IJM42) PP3986 Jun. 9, A Method of Manufacture of  6,245,247 1998 an Image Creation Apparatus (Jul. 10, 1998) (IJM43) PP3984 Jun. 9, A Method of Manufacture of  6,245,247 1998 an Image Creation Apparatus (Jul. 10, 1998) (IJM44) PP3982 Jun. 9, A Method of Manufacture of  6,231,148 1998 an Image Creation Apparatus (Jul. 10, 1998) (IJM45) Fluid Supply

Further, the present application may utilize an ink delivery system to the ink jet head. Delivery systems relating to the supply of ink to a series of ink jet nozzles are described in the following Australian provisional patent specifications, the disclosure of which are hereby incorporated by cross-reference. The serial numbers of respective corresponding U.S. patent applications are also provided for the sake of convenience.

U.S. Pat. No./ patent Australian application Provisional Filing Ser. No. and Number Date Title Filing Date PO8003 Jul. 15, Supply Method and Apparatus  6,350,023 1997 (F1) (Jul. 10, 1998) PO8005 Jul. 15, Supply Method and Apparatus  6,318,849 1997 (F2) (Jul. 10, 1998) PO9404 Sep. 23, A Device and Method (F3) 09/113,101 1997 (Jul. 10, 1998) MEMS Technology

Further, the present application may utilize advanced semiconductor microelectromechanical techniques in the construction of large arrays of ink jet printers. Suitable microelectromechanical techniques are described in the following Australian provisional patent specifications incorporated here by cross-reference. The serial numbers of respective corresponding U.S. patent applications are also provided for the sake of convenience.

U.S. Pat. No./ patent Australian application Provisional Ser. No. and Number Filing Date Title Filing Date PO7943 Jul. 15, 1997 A device (MEMS01) PO8006 Jul. 15, 1997 A device (MEMS02)  6,087,638 (Jul. 10, 1998) PO8007 Jul. 15, 1997 A device (MEMS03) 09/113,093 (Jul. 10, 1998) PO8008 Jul. 15, 1997 A device (MEMS04)  6,340,222 (Jul. 10, 1998) PO8010 Jul. 15, 1997 A device (MEMS05)  6,041,600 (Jul. 10, 1998) PO8011 Jul. 15, 1997 A device (MEMS06)  6,299,300 (Jul. 10, 1998) PO7947 Jul. 15, 1997 A device (MEMS07)  6,067,797 (Jul. 10, 1998) PO7945 Jul. 15, 1997 A device (MEMS08) 09/113,081 (Jul. 10, 1998) PO7944 Jul. 15, 1997 A device (MEMS09)  6,286,935 (Jul. 10, 1998) PO7946 Jul. 15, 1997 A device (MEMS10)  6,044,646 (Jul. 10, 1998) PO9393 Sep. 23, A Device and Method 09/113,065 1997 (MEMS11) (Jul. 10, 1998) PP0875 Dec. 12, A Device (MEMS12) 09/113,078 1997 (Jul. 10, 1998) PP0894 Dec. 12, A Device and Method 09/113,075 1997 (MEMS13) (Jul. 10, 1998) IR Technologies

Further, the present application may include the utilization of a disposable camera system such as those described in the following Australian provisional patent specifications incorporated here by cross-reference. The serial numbers of respective corresponding U.S. patent applications are also provided for the sake of convenience.

Australian U.S. Pat. No./patent application Ser. No. and Provisional Filing Number Filing Date Title Date PP0895 Dec. 12, An Image Creation Method  6,231,148 1997 and Apparatus (IR01) (Jul. 10, 1998) PP0870 Dec. 12, A Device and Method (IR02) 09/113,106 1997 (Jul. 10, 1998) PP0869 Dec. 12, A Device and Method (IR04)  6,293,658 1997 (Jul. 10, 1998) PP0887 Dec. 12, Image Creation Method and 09/113,104 1997 Apparatus (IR05) (Jul. 10, 1998) PP0885 Dec. 12, An Image Production System  6,238,033 1997 (IR06) (Jul. 10, 1998) PP0884 Dec. 12, Image Creation Method and  6,312,070 1997 Apparatus (IR10) (Jul. 10, 1998) PP0886 Dec. 12, Image Creation Method and  6,238,111 1997 Apparatus (IR12) (Jul. 10, 1998) PP0871 Dec. 12, A Device and Method (IR13) 09/113,086 1997 (Jul. 10, 1998) PP0876 Dec. 12, An Image Processing Method 09/113,094 1997 and Apparatus (IR14) (Jul. 10, 1998) PP0877 Dec. 12, A Device and Method (IR16)  6,378,970 1997 (Jul. 10, 1998) PP0878 Dec. 12, A Device and Method (IR17)  6,196,739 1997 (Jul. 10, 1998) PP0879 Dec. 12, A Device and Method (IR18) 09/112,774 1997 (Jul. 10, 1998) PP0883 Dec. 12, A Device and Method (IR19)  6,270,182 1997 (Jul. 10, 1998) PP0880 Dec. 12, A Device and Method (IR20)  6,152,619 1997 (Jul. 10, 1998) PP0881 Dec. 12, A Device and Method (IR21) 09/113,092 1997 (Jul. 10, 1998) DotCard Technologies

Further, the present application may include the utilization of a data distribution system such as that described in the following Australian provisional patent specifications incorporated here by cross-reference. The serial numbers of respective corresponding U.S. patent applications are also provided for the sake of convenience.

U.S. Pat. No./patent Australian application Provisional Filing Ser. No. and Number Date Title Filing Date PP2370 Mar. 16, Data Processing Method and 09/112,781 1998 Apparatus (Dot01) (Jul. 10, 1998) PP2371 Mar. 16, Data Processing Method and 09/113,052 1998 Apparatus (Dot02) (Jul. 10, 1998) Artcam Technologies

Further, the present application may include the utilization of camera and data processing techniques such as an Artcam type device as described in the following Australian provisional patent specifications incorporated here by cross-reference. The serial numbers of respective corresponding U.S. patent applications are also provided for the sake of convenience.

U.S. Pat. No./patent Australian application Provisional Filing Ser. No. and Number Date Title Filing Date PO7991 Jul. 15, Image Processing Method and 09/113,060 1997 Apparatus (ART01) (Jul. 10, 1998) PO7988 Jul. 15, Image Processing Method and  6,476,863 1997 Apparatus (ART02) (Jul. 10, 1998) PO7993 Jul. 15, Image Processing Method and 09/113,073 1997 Apparatus (ART03) (Jul. 10, 1998) PO9395 Sep. 23, Data Processing Method and  6,322,181 1997 Apparatus (ART04) (Jul. 10, 1998) PO8017 Jul. 15, Image Processing Method and 09/112,747 1997 Apparatus (ART06) (Jul. 10, 1998) PO8014 Jul. 15, Media Device (ART07)  6,227,648 1997 (Jul. 10, 1998) PO8025 Jul. 15, Image Processing Method and 09/112,750 1997 Apparatus (ART08) (Jul. 10, 1998) PO8032 Jul. 15, Image Processing Method and 09/112,746 1997 Apparatus (ART09) (Jul. 10, 1998) PO7999 Jul. 15, Image Processing Method and 09/112,743 1997 Apparatus (ART10) (Jul. 10, 1998) PO7998 Jul. 15, Image Processing Method and 09/112,742 1997 Apparatus (ART11) (Jul. 10, 1998) PO8031 Jul. 15, Image Processing Method and 09/112,741 1997 Apparatus (ART12) (Jul. 10, 1998) PO8030 Jul. 15, Media Device (ART13)  6,196,541 1997 (Jul. 10, 1998) PO7997 Jul. 15, Media Device (ART15)  6,195,150 1997 (Jul. 10, 1998) PO7979 Jul. 15, Media Device (ART16)  6,362,868 1997 (Jul. 10, 1998) PO8015 Jul. 15, Media Device (ART17) 09/112,738 1997 (Jul. 10, 1998) PO7978 Jul. 15, Media Device (ART18) 09/113,067 1997 (Jul. 10, 1998) PO7982 Jul. 15, Data Processing Method and  6,431,669 1997 Apparatus (ART19) (Jul. 10, 1998) PO7989 Jul. 15, Data Processing Method and  6,362,869 1997 Apparatus (ART20) (Jul. 10, 1998) PO8019 Jul. 15, Media Processing Method and  6,472,052 1997 Apparatus (ART21) (Jul. 10, 1998) PO7980 Jul. 15, Image Processing Method and  6,356,715 1997 Apparatus (ART22) (Jul. 10, 1998) PO8018 Jul. 15, Image Processing Method and 09/112,777 1997 Apparatus (ART24) (Jul. 10, 1998) PO7938 Jul. 15, Image Processing Method and 09/113,224 1997 Apparatus (ART25) (Jul. 10, 1998) PO8016 Jul. 15, Image Processing Method and  6,366,693 1997 Apparatus (ART26) (Jul. 10, 1998) PO8024 Jul. 15, Image Processing Method and  6,329,990 1997 Apparatus (ART27) (Jul. 10, 1998) PO7940 Jul. 15, Data Processing Method and 09/113,072 1997 Apparatus (ART28) (Jul. 10, 1998) PO7939 Jul. 15, Data Processing Method and 09/112,785 1997 Apparatus (ART29) (Jul. 10, 1998) PO8501 Aug. 11, Image Processing Method and  6,137,500 1997 Apparatus (ART30) (Jul. 10, 1998) PO8500 Aug. 11, Image Processing Method and 09/112,796 1997 Apparatus (ART31) (Jul. 10, 1998) PO7987 Jul. 15, Data Processing Method and 09/113,071 1997 Apparatus (ART32) (Jul. 10, 1998) PO8022 Jul. 15, Image Processing Method and  6,398,328 1997 Apparatus (ART33) (Jul. 10, 1998) PO8497 Aug. 11, Image Processing Method and 09/113,090 1997 Apparatus (ART34) (Jul. 10, 1998) PO8020 Jul. 15, Data Processing Method and  6,431,704 1997 Apparatus (ART38) (Jul. 10, 1998) PO8023 Jul. 15, Data Processing Method and 09/113,222 1997 Apparatus (ART39) (Jul. 10, 1998) PO8504 Aug. 11, Image Processing Method and 09/112,786 1997 Apparatus (ART42) (Jul. 10, 1998) PO8000 Jul. 15, Data Processing Method and  6,415,054 1997 Apparatus (ART43) (Jul. 10, 1998) PO7977 Jul. 15, Data Processing Method and 09/112,782 1997 Apparatus (ART44) (Jul. 10, 1998) PO7934 Jul. 15, Data Processing Method and 09/113,056 1997 Apparatus (ART45) (Jul. 10, 1998) PO7990 Jul. 15, Data Processing Method and 09/113,059 1997 Apparatus (ART46) (Jul. 10, 1998) PO8499 Aug. 11, Image Processing Method and  6,486,886 1997 Apparatus (ART47) (Jul. 10, 1998) PO8502 Aug. 11, Image Processing Method and  6,381,361 1997 Apparatus (ART48) (Jul. 10, 1998) PO7981 Jul. 15, Data Processing Method and  6,317,192 1997 Apparatus (ART50) (Jul. 10, 1998) PO7986 Jul. 15, Data Processing Method and 09/113,057 1997 Apparatus (ART51) (Jul. 10, 1998) PO7983 Jul. 15, Data Processing Method and 09/113,054 1997 Apparatus (ART52) (Jul. 10, 1998) PO8026 Jul. 15, Image Processing Method and 09/112,752 1997 Apparatus (ART53) (Jul. 10, 1998) PO8027 Jul. 15, Image Processing Method and 09/112,759 1997 Apparatus (ART54) (Jul. 10, 1998) PO8028 Jul. 15, Image Processing Method and 09/112,757 1997 Apparatus (ART56) (Jul. 10, 1998) PO9394 Sep. 23, Image Processing Method and  6,357,135 1997 Apparatus (ART57) (Jul. 10, 1998) PO9396 Sep. 23, Data Processing Method and 09/113,107 1997 Apparatus (ART58) (Jul. 10, 1998) PO9397 Sep. 23, Data Processing Method and  6,271,931 1997 Apparatus (ART59) (Jul. 10, 1998) PO9398 Sep. 23, Data Processing Method and  6,353,772 1997 Apparatus (ART60) (Jul. 10, 1998) PO9399 Sep. 23, Data Processing Method and  6,106,147 1997 Apparatus (ART61) (Jul. 10, 1998) PO9400 Sep. 23, Data Processing Method and 09/112,790 1997 Apparatus (ART62) (Jul. 10, 1998) PO9401 Sep. 23, Data Processing Method and  6,304,291 1997 Apparatus (ART63) (Jul. 10, 1998) PO9402 Sep. 23, Data Processing Method and 09/112,788 1997 Apparatus (ART64) (Jul. 10, 1998) PO9403 Sep. 23, Data Processing Method and  6,305,770 1997 Apparatus (ART65) (Jul. 10, 1998) PO9405 Sep. 23, Data Processing Method and  6,289,262 1997 Apparatus (ART66) (Jul. 10, 1998) PP0959 Dec. 16, A Data Processing Method  6,315,200 1997 and Apparatus (ART68) (Jul. 10, 1998) PP1397 Jan. 19, A Media Device (ART69)  6,217,165 1998 (Jul. 10, 1998) 

1. An image capture and proccssing integrated circuit comprising: an image sensor including a plurality of sensor columns for capturing an image; a plurality of analogue-to-digital converters (ADC's) that are connected to the image sensor to convert analogue signals generated by the image sensor into digital signals; image processing circuitry that is connected to the ADC's to carry out image processing operations on the digital signals; a print head interface that is connected to the image processing circuitry to receive data from the image processing circuitry and to format that data for a printhead; and a high current drive transistor configured to drive a capping solenoid of the printhead, wherein the high current drive transistor is driven when the image sensor is not in use so as to avoid effecting the captured image via a voltage fluctuation in the image capture and processing integrated circuit; wherein the integrated circuit defines a CMOS active pixel sensor array, and wherein the integrated circuit incorporates a plurality of analog signal processors, each analog signal processor being dedicated to process one or more signals generated by a respective one of the plurality of sensor columns, wherein the plurality of analog signal processors are configured to carry out enhancement processes on analog signals generated by the active pixel sensor array.
 2. An image capture and processing integrated circuit as claimed in claim 1, which includes a memory device that is interposed between the image sensor and the image processing circuitry to store data relating to an image sensed by the image sensor integrated circuit.
 3. An image capture and processing integrated circuit as claimed in claim 1, in which the image processing circuitry includes color interpolation circuitry to interpolate pixel data.
 4. An image capture and processing integrated circuit as claimed in claim 1, in which the image processing circuitry includes convolver circuitry that is configured to apply a convolution process to the image data.
 5. An image capture and processing integrated circuit as claimed in claim 1, in which the print head interface is configured to format the data correctly for a pagewidth printhead.
 6. An image capture and processing integrated circuit as claimed in claim 1, which is a single integrated circuit.
 7. A camera system which includes the image capture and processing integrated circuit as claimed in claim
 1. 